Power Management Selection Guide 2015 01_00
Transcription
Power Management Selection Guide 2015 01_00
Power Management Selection Guide 2015 www.infineon.com/solutionfinder Mobile Catalogue Dear Customer, Our world is facing huge challenges The world population is rising, energy demand is increasing rapidly and we are seeing alarming climate changes. It is essential to preserve our natural resources, choose renewable energy forms and put tremendous efforts into optimizing energy efficiency. Our solutions maximize electricity savings along the entire supply chain – from generation to distribution to consumption – setting benchmarks for energy efficiency and power density. Our passion is to understand your systems and offer the best solutions By using our products and systems, you gain in innovation and costperformance in your applications – including Servers, Telecom Systems, Computers, Game Consoles, Smart Phones, Cellular Infrastructure and Lighting Solutions. Product families such as CoolMOS™ , OptiMOS™ or the combination of power transistors and ICs in the most advanced packaging technologies as well as digital power platforms enable a completely new level of efficiency and compactness. We are proud that well-known customers trust our competence and use our solutions for their competitive advantage. Infineon is becoming even stronger and we are looking forward to unleashing great potential in the power industry – our experts combine Infineon semiconductors and control architecture in a unique way to make your products more efficient, more cost effective and altogether more successful. Please be invited to let our new Power Management Selection Guide 2015 inspire you to find the right energy efficient products and solutions for your purpose! 尊敬的用户, 我们的世界正面临着巨大的挑战 世界人口正在增长,能源需求急剧增加,我们面临着惊人的气候变化。我们必须 保护我们的自然资源,选择可再生能源,并且在优化能源效率方面付出极大的努 力。我们的解决方案是最大限度地在整个从发电、输送到用电的供应链中节省电 力,以此为能源效率和功率密度设定行业标杆。 我们的动力是了解您的系统,并提供最好的解决方案。 通过使用我们的产品和系统,你获得了创新和性价比高的应用,包括服务器、电 信系统、电脑、游戏机、智能手机、蜂窝通信基础设施和照明解决方案。产品系 列如CoolMOS™ 或OptiMOS™ ,以最先进的封装技术结合的功率晶体管和专用 集成电路,以及数字电源平台,造就了全新水平的效率和紧凑。知名客户信任我 们的能力,使用我们的解决方案来提高其竞争优势,为此我们感到很自豪。英飞 凌日益强大,我们期待着释放在电力行业的巨大潜力-我们的专家将英飞凌半导 体和控制架构以一种独特的方式结合,使得您的产品更高效,更经济,更成功。 请让我们新版的2015电源管理选型指南带您找到符合您目标的正确的节能产品和 解决方案。 Andreas Urschitz Division President of Power Management & Multimarket 电源管理及多元化市场事业部总裁 Content Power Management Applications DC/DC Computing Notebook Server, Desktop and Graphic Cards Point-of-Load Uninterruptable Power Supply SMPS Charger Adapter PC Silverbox TV Power Server Power Supply Telecom Power Supply E-Mobility Solar Major Home Appliances Induction Cooking Inverterized Drives Lighting Industrial Welding Battery Powered Applications Light Electric Vehicles Wireless Power 8 8 8 9 10 11 12 12 14 16 18 20 23 26 30 34 34 35 36 39 40 42 44 Segment Low Voltage – OptiMOS™ 46 Segment High Voltage – CoolMOS™ 70 Segment Silicon Carbide 88 Segment IGBT 98 Segment Silicon Power Diodes 114 Segment Power ICs 118 Segment Microcontrollers 164 Segment Sensors 168 Packages 174 Soloreiust cone pratende We shape Power Management We live Energy Efficiency www.infineon.com/power 5 .dp digital power™ 2.0 .dp digital power™ 2.0 Simplify Innovation Power supply development migrates from analog to digital design, to achieve smaller form factors and higher efficiency. Infineon is introducing .dp digital power™ 2.0 to simplify your innovations. The new digital IC family is the first all-in-one package solution that integrates a digital power controller with key peripherals. .dp digital power 2.0 will be introduced to the broader market by 2015. Key Benefits of a digital switched mode Power Supply Technical enhancement and cost saving go hand-in-hand Firmware gives flexibility over fixed analog design Cost saving and faster time to market increase competitiveness Your advantage More flexibility through digital approach Simplify the management of product variation Shorten development cycles down by 70% Offer room for customer innovation and own IP Advanced energy efficiency Reduced system cost and BOM The value added For lighting market customers .dp helps to cope with the paradigm shift of LED requirements and to solve actual lighting challenges. For Power Supply customers in the mid-performance sector .dp helps to comply with energy efficiency criteria and provides a much better stand-by management. www.infineon.com/digitalpower 6 Increase efficiency Reduce costs .dp power supplies achieve smaller form factors and higher efficiency. .dp cuts development cycles, OPEX and BOM considerably! Maximize flexibility Boost performance Adapters with .dp inside charge mobile devices significantly faster. LED drivers with .dp inside improve the lifetime of valuable LED components. 7 Notebook DC/DC Computing Small and Cool System Power for Notebooks Benchmark technologies significantly improve switching losses in power stages and drivers and thus improve battery lifetime and system reliability. Highest efficiency at all load conditions enables system designers to overcome thermal challenges to reach a new level of system miniaturization. Our latest portfolio of Notebook products is consequently optimized along the requirements of the next generation Notebook platforms and easy to design-in. AC Adapters OptiMOS™ Battery Charger Chip Set, DDR, I/O, other peripheral loads DC/DC PWM Controller OptiMOS™ CPU, GPU OptiMOS™ 8 Notebook Topology Voltage Class Technology Selection DC/DC Buck Converter 30V OptiMOS™ Recommendation Controller Buck Converter See page 137 for further information Applications Server DC/DC Computing Highest Power Density for Server, Desktop and Graphic Cards Power management system solutions based on OptiMOS™ technology increase Energy Efficiency in all load conditions, reduce required PCB real estate and are easy to use. Our benchmark solutions demonstrate greatly increased efficiency, even at high currents and high switching frequencies. This supports system designers to achieve efficiency as well as power and thermal requirements with a reduced number of phases and thus save overall system cost. Gate Driver OptiMOS™ Gate Driver OptiMOS™ DC/DC PWM Controller DC/DC PWM Controller Chip Set, DDR, I/O, other peripheral loads SIP CPU, GPU Clamping, Level Shifters and General Purpose Gate Driver Server, Desktop and Graphic Cards Topology Voltage Class Technology Selection DC/DC Buck Converter 25V OptiMOS™ Recommendation Buck Converter 30V OptiMOS™ Reference Gate Driver Buck Converter 12V PX3517 Recommendation TDA21320 Recommendation SIP Buck Converter 16V Controller Buck Converter See page 137 for further information 9 Point of Load DC/DC Computing Point of Load Power Management for Superior Performance Our power architectures address the need for more accurate and efficient power delivery to support increasingly challenging requirements of today’s microprocessors, memories, ASICs and FPGAs. The voltage regulators can be optimized and configured while actively regulating; the final configuration is then permanently stored inside the controller chip non-volatile memory eliminating the need for external configuration components. Combined with DrBlade™ 2 (TDA21320) the voltage regulators can achieve > 95% efficiency depending on operating conditions. Designs with output voltages of up to 5.0V are supported. Point of Load is used in Datacom, Computing and Telecom. VIN (0.5V - 16V) DC/DC PWM Controller Driver Inductor VOUT (0.5V - 5V) Output Capacitance GND PX7x4xH Family 10 DrBlade™ 2 All in one: Driver + high side + low side MOSFET Point of Load Topology Technology Selection Controller Buck Converter Highly parameterized fully digital controller Recommendation Power Stage Buck Converter DrBlade™ 2 – SiP (driver and FETs) Recommendation Applications UPS Uninterruptable Power Supply (UPS) Attractive Solutions for Highest Efficiency and Power Density Infineon offers a wide range of cost-effective products for Uninterruptable Power Supply (UPS), for all its stages. This includes IGBTs, diodes and control ICs for AC/DC and DC/AC stages, as well as for the battery charge control circuitry and switches for the auxiliary Power Supply. The recently launched 650V TRENCHSTOP™ 5 IGBTs in combination with Rapid diodes support the trends towards continuously increasing system efficiency, power density and reducing the cost of ownership for UPS users. Control ICs AC VIN VBULK PFC Charge Controller VOUT Inverter DC VBAT AUX Stage Topology Voltage Class Technology Selection PFC Boost PFC 600V / 1200V TRENCHSTOP™ Ease-of-use Boost PFC 600V / 1200V HighSpeed 3 Efficiency Boost PFC 650V TRENCHSTOP™ 5 Efficiency Boost PFC 650V Rapid Diode Efficiency NPC1 600V TRENCHSTOP™ Ease-of-use NPC1 600V HighSpeed 3 Efficiency NPC1 650V TRENCHSTOP™ 5 Efficiency NPC1 650V Rapid Diode Efficiency NPC2 1200V TRENCHSTOP™ 2 Ease-of-use NPC2 1200V HighSpeed 3 Efficiency NPC2 650V TRENCHSTOP™ 5 Efficiency NPC2 650V Rapid Diode Efficiency Charger controller Half bridge 1200V HighSpeed 3 Efficiency Driver IC - 1200V EiceDriver™ Compact Recommendation AUX - 650V-800V CoolSET™ Recommendation Inverter 11 Charger SMPS Charger High power density and cost effective Power Supplies can be designed by operating the converter at a higher switching frequency to avoid a considerable increase in transformer and output capacitor size. In realizing the required thermal performance and EMI behavior, power devices with lower FOM (RDS(on)*Qg) and controlled switching behavior enable effective and fast R&D development due to their lower losses and smoother waveforms. Semiconductor devices in SMD packages enable optimal PCB layout through minimal footprint and are very well fit for automatized large volume production. The CoolMOS™ high voltage MOSFET and OptiMOS™ low voltage MOSFETs portfolios enable high power density designs whilst keeping your thermal requirements under control. High Voltage MOSFETs An efficiency optimized solution can be achieved with CoolMOS™ C6/E6 families. Both families include a gate resistor which gives a good balance in ease-of-use, efficiency and reduced EMI. For cost sensitive Consumer applications we recommend CoolMOS™ CE family. This technology offers smoother waveforms, lesser dv/dt and RFI and an internal gate resistor for ease-of-use. Nevertheless, our technology still achieves better efficiency and thermal behavior than standard MOSFETs. Topology Voltage Class Technology Benefit Flyback 600V/650V CoolMOS™ C6/E6 High efficiency due to lower Rg,int (E6) Easy control of switching behavior Flyback 600V/650V CoolMOS™ CE Best price competitive CoolMOS™ family Lower switching losses vs. standard MOSFET Controlled dv/dt and di/dt for better EMI Low Voltage MOSFETs The OptiMOS™ 60V, 80V and 100V families have the lowest RDS(on) when compared to other similar devices. This helps to keep conduction losses to a minimum, benefiting the thermal management of the charger. The lower output charge of the OptiMOS™ family reduces the overshoot in the Synchronous Rectification stage. 12 Topology Voltage Class Technology Benefit Flyback 60V - 100V OptiMOS™ 5 Low conduction losses, reduced overshoot Synchronous Rectification 60V - 100V OptiMOS™ 5 Low conduction losses, reduced overshoot Applications Charger Control ICs Quasi-Resonant Flyback topology is known to have high efficiency and low EMI performance compared with the Fixed Frequency Flyback topology as the system is switching at the valley point for each switching cycle. ICE2QS03G inherits the QR topology and enhances performance through 7 valley switching points to reduce the switching frequency. Also, the patented active burst mode feature enhances the light load standby power. Topology Voltage Class Technology Benefit QR Flyback IC 500V ICE2QS03G High efficiency, low standby power Discrete Solution Blockdiagram FF/QR PWM controller e.g. ICE3XS03LJG ICE3QS03G Output QR flyback controllers EMI Filter 600V CoolMOS™ C3/CP/C6/E6 800V CoolMOS™ C3 e.g. IPA60R600CP SPA06N80C3 OptiMOS™ 3 e.g. BSZ100N06LS3 Quick Charge Controller Main converter Quasi-resonant or FF flyback Synchronous Rectification Controller 13 Adapter SMPS Adapter Manufacturing of slimmer and lighter Adapters requires ICs enabling high efficiency with good EMI performance and low standby power and cost effective MOSFETs in small packages that feature good electromagnetic interference (EMI) and excellent thermal performance. Infineon offers a wide range of products for Adapters including high voltage MOSFETs and control ICs for PFC and PWM stages, as well as low voltage MOSFETs for Synchronous Rectification. With these products, Infineon supports the trend towards a significantly higher efficiency level, especially in partial load conditions, as well as miniaturization of the Adapter. Especially versatile are the CoolMOS™ C6/E6 and P6 families which combine high efficiency with ease-of-use. For Synchronous Rectification, Infineon’s OptiMOS™ series offers extremely low on-state resistance and low capacitances. New control ICs support topologies such as Quasi-Resonant Flyback and LLC, which have become increasingly significant within the Notebook Adapter segment. In order to offer a complete power electronics solution perfectly complementing Infineon’s portfolio, the new hyperfast Rapid Silicon diode family has been introduced for the PFC stage. Regional regulations and a general increased sensitivity toward the containment of electronic waste are pointing towards the adoption of universal Adapters. The implementations methodologies and protocols are not yet harmonized, however Infineon is already closely monitoring and partnering with the decision makers to timely insure the offer of a competitive semiconductor solution. The capability to efficiently manage different power classes and protocols will be key in this application and Infineon is getting ready for supporting Adapter makers in this challenge. High Voltage MOSFETs For efficiency driven and high power density applications, CoolMOS™ P6 family is the recommended solution due to low switching losses even in high switching frequency operation. For standard Adapters, where ease of design and good EMI behavior are the main priorities, CoolMOS™ CE offers higher internal gate resistance for softer voltage and current transition. Topology Voltage Class Technology Benefit DCM PFC 600V CoolMOS™ P6 Flyback 600V CoolMOS™ P6 Fast switching speed for improved efficiency and thermals Reduced gate charge for enhanced light load efficiency Optimized Vgs threshold for lower turn-off losses HB LLC 600V CoolMOS™ P6 DCM PFC 500V/600V CoolMOS™ CE Flyback 500V/600V CoolMOS™ CE HB LLC 500V/600V CoolMOS™ CE DCM/CCM PFC 650V CoolMOS™ C6/E6 HB LLC 650V CoolMOS™ C6/E6 Easy control of switching behavior due to higher Rg,int Better transition losses vs. standard MOSFET Easy control of switching behavior even in not optimized layout Better switching losses in comparison with its predecessor Rugged body diode which prevents device failure during hard commutation Low Voltage MOSFETs The OptiMOS™ 80V, 100V and 120V families have the lowest RDS(on) when compared to other similar devices. This helps to keep conduction losses to a minimum, benefiting the thermal management. The lower output charge of the OptiMOS™ family reduces the overshoot in the Synchronous Rectification stage. 14 Topology Voltage Class Technology Benefit Flyback 80V - 120V OptiMOS™ Low conduction losses, reduced overshoot Applications Adapter Boost Diodes For DCM PFC topologies, a low forward voltage diode is recommended. Rapid 1 diodes have a low and temperaturestable forward voltage to simplify design effort. Topology Voltage Class Technology Benefit DCM PFC 650V Rapid 1 Low conduction losses Control ICs ICE2QS03G can achieve high efficiency and low standby power performance as it adopts the QR topology and Infineon’s patented active burst mode feature. TDA486x (G) is a DCM PFC IC which can achieve a power factor close to 1 and low Total Harmonic Distortion (THD). Topology Voltage Class Technology Benefit QR Flyback IC 500V ICE2QS03G High efficiency, high standby power DCM PFC IC 650V TDA486x(G) High PFC, low THD Blockdiagram USB Port Vout (5,9,12,20V) 85...265VAC D+ D– Gate VCC SR Gate FB CS Gate HV_IN Adaptive Vout PWM controller FB Wake up Int* FB D+ D– 15 PC Silverbox SMPS PC Silverbox Latest PC models dramatically cut active and standby energy consumption by implementing more efficient Power Supply Units (PSU) and low power processors and chipsets. Today’s requirement for OEM PC power is a small form factor with better performance and embedded diagnostics. An intelligent control scheme that enables the adaption of load variation to minimize power consumption, together with optimized power semiconductors, is the key in meeting market demands. Proven reference designs are available to help designers to develop the best-possible PC Power Supply solutions – from greater efficiency to lower overall system cost. High Voltage MOSFETs CoolMOS™ P6 family is the recommended solution to achieve a compact form factor with the highest efficiency even at very light load conditions. This is due to its optimized Eon and Eoff losses without the compromise in performance during hard commutation. CoolMOS™ CE is an alternative option for a price driven segment where the main concern is the maintenance of design robustness even if the board layout is not optimized. Topology Voltage Class Technology Benefit DCM/CCM PFC, HB LLC 600V CoolMOS™ P6 Fast switching speed for improved efficiency and thermals Low gate charge for enhanced light load efficiency and low power consumption at no load condition Optimized Vgs threshold for lower turn-off losses Rugged body diode for HB LLC application DCM/CCM PFC, HB LLC 600V CoolMOS™ C6/E6 Easy control of switching behavior even in not optimized layout Better switching losses in comparison with its predecessor Rugged body diode which prevents device failure during hard DCM/CCM PFC, HB LLC 500V CoolMOS™ CE Easy control of switching behavior due to higher Rg,int Better transition losses vs. standard MOSFET commutation Low Voltage MOSFETs For Synchronous Rectification and DC/DC, we recommend our OptiMOS™ 40V and 60V families which combine extremely low on-state resistance with low capacitances. Topology Voltage Class Technology Benefit HB LLC + center-tap 40V OptiMOS™ Optimized cost/performance, layout tolerance HB LLC + center-tap 60V OptiMOS™ Layout tolerance, low thermals Boost Diodes For DCM PFC topologies, a low forward voltage diode is recommended. Rapid 1 diodes have a low and temperaturestable forward voltage to simplify design effort. For CCM PFC topologies, a low reverse recovery charge diode is used to minimize diode switching losses. Rapid 2 diodes have a low peak reverse recovery current that lowers both diode switching losses and PFC switch turn-on losses. 16 Topology Voltage Class Technology Benefit DCM PFC 650V Rapid 1 Low conduction losses CCM PFC 650V Rapid 2 Low reverse recovery losses and PFC switch turn-on losses Applications PC Silverbox Control ICs QR/FF CoolSET™ , either 650V or 800V, is the best choice for the auxiliary power. Most importantly it can achieve very low standby power. It is cost effective and easy to use. ICE3PCS0xG is the latest CCM PFC IC which implements digital control and can achieve high PFC, low THD and fast response. ICE1/2HS01G is the novel resonant LLC half-bridge controller IC which is easy to use and can achieve high efficiency and low EMI by ZVS switching. Topology Voltage Class Technology Benefit QR/FF Flyback CoolSET™ 650V/800V ICE2QRxx65/80(Z)(G) ICE3xRxx65/80J(Z)(G) Low standby power, high efficiency CCM PFC IC 800V ICE3PCS0xG High PFC, low THD HB LLC IC 650V ICE1HS01G-1 ICE2HS01G High efficiency, low EMI Blockdiagram Driver + OptiMOS™ DC/DC PFC CoolMOS™ CoolMOS™ CoolMOS™ SiC Diode 5V OptiMOS™ DC/DC 3V3 12V OptiMOS™ PWM 5V CoolSET™ 17 TV Power SMPS TV Power In addition to their outstanding image quality, new generation TVs gain attention for their user interface, low power consumption and for the slim silhouette. Power Supply Unit (PSU) with a high degree of embedded intelligence and a low profile to maintain the TV’s slim appearance are required. Infineon’s Power Supplies feature power metering and communication of diagnostics, characterized by high efficiency, good thermal and EMI performance while keeping short design cycles, avoiding R&D cost increase and still being highly cost-effective. High Voltage MOSFETs A low profile Power Supply within a demanding thermal environment will require excellent thermal performance parts with low losses even at high switching frequencies. CoolMOS™ P6 family addresses this challenge with enhanced turn-on and turn-off losses which results in better efficiency. For applications that do not operate at high switching frequencies, CoolMOS™ CE/C6/E6 provide gentle switching behavior due to higher output capacitance (Coss) and internal gate resistor. This results in low RFI and minimal voltage oscillations resulting in unwanted parasitic due to PCB layout. Topology Voltage Class Technology Benefit DCM PFC, HB LLC 600V CoolMOS™ P6 Fast switching speed for improved efficiency and thermals Low gate charge for enhanced light load efficiency and low power consumption at no load condition Optimized Vgs threshold for lower turn-off losses Rugged body diode which prevents device failure during hard commutation DCM PFC, HB LLC 500V/600V CoolMOS™ CE Easy control of switching behavior even in not optimized layout Rugged body diode which prevents device failure during hard commutation Better switching losses in comparison with its predecessor DCM PFC, HB LLC 600V CoolMOS™ C6/E6 Easy control of switching behavior even in not optimized layout Rugged body diode which prevents device failure during hard commutation Better switching losses in comparison with its predecessor Low Voltage MOSFETs The OptiMOS™ 5 100V family, along with the OptiMOS™ 3 100V, with the lowest RDS(on) when compared to other similar devices, help to keep conduction losses to a minimum, benefiting thermal management. The OptiMOS™ 5 family has reduced output charge, which reduces the overshoot in the Synchronous Rectification stage. Topology Voltage Class Technology Benefit Flyback 100V OptiMOS™ 3/5 Low conduction losses, reduced overshoot Boost Diodes For DCM PFC topologies, a low forward voltage diode is recommended. Rapid 1 diodes have a low and temperaturestable forward voltage to simplify design effort. 18 Topology Voltage Class Technology Benefit DCM PFC 650V Rapid 1 Low conduction losses Applications TV Power Control ICs QR/FF CoolSET™ 650V is the best choice for the auxiliary power. Most importantly, it can achieve very low standby power. TDA486x(G) is a DCM PFC IC which can achieve a power factor close to 1 and low Total Harmonic Distortion (THD). ICE1/2HS01G is the novel resonant LLC half bridge controller IC which is easy to use and can achieve high efficiency and low EMI by ZVS switching. To address the market needs for lower system cost, the upcoming controller ICs will implement efficient digital control modes during standby. This enables the removal of the auxiliary Power Supply while meeting the stringent regulative requirements. A full set of protection features required in TV applications and flexible IC parameterization will complement these innovative IC solutions. Topology Voltage Class Technology Benefit QR/FF Flyback CoolSET™ 650V ICE2QRxx65(Z)(G) ICE3xRxx65J(Z)(G) Low standby power, high efficiency DCM PFC IC 650V TDA486x(G) High PFC, low THD HB LLC IC 650V ICE1HS01G-1 ICE2HS01G High efficiency, low EMI Blockdiagram SiC Diode e.g. IDT02S60C SDT02S60C CoolMOS™ 600V C3, CP, C6, E6, P6 500V CE Main converter Half bridge resonant converter Pulse Transformer EMI Filter 180V output LED Backlight 18V/12V output System & Audio HB LLC controller PFC Controllers e.g. ICE3PCS0X ICE2PC20X TDA4863-2 ICE1HS01G-1 PFC Controller CoolMOS™ 600V C3, CP, C6, E6, P6 500V CE CoolSET™ new Series F3R e.g. ICE3BR4765J 5V Standby & Microcontroller controller PFC pre-regulator Boost converter Standby converter Fixed frequency flyback 19 Server Power Supply SMPS Server Power Supply The rising cost of energy and environmental concerns makes SMPS efficiency optimization a key requirement across the entire load range for Server and Data Center design. This challenging task is combined with the requirement for higher power. In the PFC stage and in general hard switching topologies used in Server applications, Infineon proposes CoolMOS™ C7 family with the lowest FOM RDS(on) *Qg and RDS(on) *Eoss. This provides the lowest switching losses necessary in fast switching needed in high-end Server SMPS, optimizing the efficiency starting from very light load operation. The very compact SMD packages such as ThinPAK offer benefits in space and power density, and are used with Infineon’s new industry standard non-isolated driver family 2EDN752x (available from mid 2015). Complementary to CoolMOS™ C7 in high efficiency PFC is the SiC diodes Generation 5 family. The CoolMOS™ P6 family offers a good compromise between price and performance. This is valuable in both PFC and HV DC/DC stages where the low Qg and turn-off losses are important benefits, especially in the case of high switching frequency operation and high light load efficiency requirements. In applications with a low output voltage and high output current, further efficiency improvements have been made possible by the continuous reduction of onresistance by Infineon’s low-voltage OptiMOS™ MOSFET series used in the Synchronous Rectification stage. High Voltage MOSFETs The new C7 series offers Best-in-Class performance in CCM Mode PFC enabling highest efficiency to be achieved over the full load range. The world best Ron*A enables smaller footprint packages to be used bringing benefits in power density. The low Qg achieves better light load efficiency – an enhanced requirement in today’s Server SMPS. Also, the CoolMOS™ C7 enables moving to higher switching frequencies without loss in efficiency, bringing benefits in power density by reducing the size of magnetic components. P6 is a well-balanced product family, which brings high efficiency in PFC topology, but due to its rugged body diode, can also be used in resonant DC/DC topologies such as LLC. The reduced Qg leads to benefits in light load efficiency. Functional Block Topology Voltage Class Technology Benefit PFC CCM/interleaved PFC; TTF 650V CoolMOS™ C7 Best FOM RDS(on)*Qg and RDS(on)*Eoss Lowest RDS(on) per package Low dependency of switching losses form Rg, ext PFC and PWM CCM/interleaved PFC; TTF HB LLC 600V CoolMOS™ P6 Fast switching speed for improved efficiency and thermals Low gate charge for enhanced light load efficiency and low power consumption at no load condition Optimized Vgs threshold for lower turn-off losses Rugged body diode which prevents device failure during hard commutation SiC Diodes The recommended diode for CCM PFC applications is the 650V thinQ!™ SiC Schottky Diode Generation 5, which include Infineon’s leading edge technologies, such as diffusion soldering process and wafer thinning technology. These Generation 5 products provide ~ 25% lower VF over previous generations. The result is a new family of products showing improved efficiency over all load conditions, coming from both the improved thermal characteristics and an improved Figure-of-Merit (QC x VF). 20 Functional Block Topology Voltage Class Technology Benefit PFC CCM/interleaved PFC 650V SiC Generation 5 Low FOM VF*QC Applications Server Power Supply Low Voltage MOSFETs Functional Block Topology Voltage Class Technology Benefit Synchronous Rectification HB LLC + center-tap 40V OptiMOS™ High efficiency over whole load range, layout tolerance ITTF 60V OptiMOS™ High efficiency, low thermals, low VDS overshoot ZVS PS FB + center-tap 80V OptiMOS™ High efficiency over whole load range, low VDS overshoot and oscillations Control ICs Since the control has a crucial role in the optimal SMPS design, Infineon also proposes families of analog (ICEXX / TDAXX families) and digital controllers (XMC family) able to meet different needs, including power management and digital communication topics. QR/FF CoolSET™ 800V, is the best choice for the auxiliary power. Most importantly, it can achieve very low standby power. It is cost effective and easy to use. ICE3PCS0xG is the latest CCM PFC IC which implements digital control and can achieve high PFC, low THD and fast response. ICE1/2HS01G is the novel resonant LLC half bridge controller IC which is easy to use and can achieve high efficiency and low EMI by ZVS switching. Functional Block Topology Voltage Class Technology Benefit Auxilliary Power Supply QR/FF Flyback CoolSET™ 800V ICE2QRxx80(Z)(G) ICE3xRxx80J(Z)(G) Low standby power, High efficiency PFC CCM PFC IC 800V ICE3PCS0xG High PFC, Low THD PWM HB LLC IC 800V ICE1HS01G-1 ICE2HS01G High efficiency, low EMI PFC and PWM PFC/LLC/ZVS PS FB/TTF 800V XMC Flexibility, HR PWM, digital communication IGBTs For price optimization, Infineon offers two excellent alternatives. The TRENCHSTOP™ 5 technology provides outstanding performance at excellent price point which is ideal for PFC and inverter stages addressing the Gold efficiency standard. The TRENCHSTOP™ 5 features a very low Qg to achieve high light load efficiency. The H5 is suitable for plug & play replacement of MOSFET while F5 version is optimized for high efficiency solutions. Both the H5 and F5 include an ultra-fast discrete free-wheeling diode which has been optimized for improved ruggedness in ZVS and LLC topologies. Functional Block Topology Voltage Class Technology Benefit PFC CCM/interleaved PFC 650V TRENCHSTOP™ H5 Ease-of-use CCM/interleaved PFC 650V TRENCHSTOP™ F5 High efficiency in low inductance designs PWM ZVS PS FB; LLC 650V TRENCHSTOP™ H5 Improved ruggedness and ease-of-use ZVS PS FB; LLC, TTF 650V TRENCHSTOP™ F5 Improved ruggedness and high efficiency in low inductance designs 21 Server Power Supply Boost Diodes In CCM PFC topologies, a low reverse recovery charge diode is used to minimize diode switching losses. Rapid 2 diodes have a low peak reverse recovery current that lowers both diode switching losses and PFC switch turn-on losses. IGBT and Rapid diode together provide excellent efficiency up to 100kHz, particularly under light load conditions. Functional Block PFC Topology CCM/interleaved PFC Voltage Class 650V Technology Benefit Rapid 2 Low reverse recovery losses and PFC switch turn-on losses, common-cathode configuration Blockdiagram 90...265VAC AUX SMPS DCM Flyback QR Flyback PFC Classic Interleaved Bridgelsee CoolMOS™ HV DC/DC I-TTF LLC ZVS PS FB CoolMOS™ 12Vsb Main XFMR Synchronous Rectification + Or-ing OptiMOS™ 12V IC Driver Gate XFMR Primary Digital Controller XMC4200 22 IC Driver Photocoupler RS232 Secondary Digital Controller XMC4200 UART or PMBus Applications Telecom Power Supply SMPS Telecom Power Supply The telecommunication industry providing data, voice and video is nowadays continuously growing supported by the expansion into the new markets, especially in Asia, accelerated by the spread of the wireless and broadband technologies. The outstanding improvements in Telecom SMPS performance achieved in the past 10 years have been primarily brought by the dramatic reduction of the on-resistance achieved in high voltage MOSFETs using the revolutionary Superjunction principle, introduced by Infineon at the end of the nineties in the CoolMOS™ series and equally impressive improvements in reverse-recovery characteristics of high voltage SiC (Silicon Carbide) diodes. In order to achieve the new challenging efficiency targets the Synchronous Rectification has become increasingly popular even in the typically high output voltage of telecom rectifiers. High Voltage MOSFETs The CoolMOS™ C7 series offers Best-in-Class performance in CCM Mode PFC enabling highest efficiency to be achieved over the full load range. The world best Ron*A enables smaller footprint packages to be used bringing benefits in power density. The low Qg achieves better light load efficiency – an enhanced requirement in today’s Server SMPS. Also, the CoolMOS™ C7 enables moving to higher switching frequencies without loss in efficiency, bringing benefits in power density by reducing the size of magnetic components. CoolMOS™ P6 is a well-balanced product family, which brings high efficiency in PFC topology, but due to its rugged body diode, can also be used in resonant DC/DC topologies such as LLC. The reduced Qg leads to benefits in light load efficiency. For ZVS topologies in the HV DC/DC Stages, Infineon has developed the CoolMOS™ CFD2 family, combining the requirements of high performance with the high reliability given by the Fast Body Diode concept. Functional Block Topology Voltage Class Technology Benefit PFC CCM/interleaved PFC; TTF 650V CoolMOS™ C7 Best FOM RDS(on)*Qg and RDS(on)*Eoss Lowest RDS(on) per package Low dependency of switching losses form Rg,ext PWM Resonant PFC; Resonant HV DC/DC stages HB LLC or ZVS PS 650V CoolMOS™ CFD2 Significant Qg reduction compared CFD1 technology Defined trr, max and Qrr, max values Lower price compared to CFD1 technology CCM/interleaved PFC; TTF HB LLC 600V CoolMOS™ P6 Fast switching speed for improved efficiency and thermals Low gate charge for enhanced light load efficiency and low power consumption at no load condition Optimized Vgs threshold for lower turn-off losses Rugged body diode which prevents device failure during hard commutation 23 Telecom Power Supply Driver ICs Functional Block Topology Voltage Class Technology Benefit PFC CCM/interleaved PFC 1200V 1ED compact Very high CMTI Functional Block Topology Voltage Class Technology Benefit PFC CCM/interleaved PFC 650V SiC Generation 5 Low FOM VF*QC Voltage Class SiC Diodes Low Voltage MOSFETs Functional Block Topology Technology Benefit Synchronous Rectification Synchronous 80V - 200V Rectification MOSFET OptiMOS™ Industry’s lowest FOM (RDS(on)*Qg) leading to high efficiency at good Or-ing Or-ing MOSFET 60V - 150V OptiMOS™ Battery Protection MOSFET 60V - 150V OptiMOS™ Small Signal Isolated DC/DC Primary Side PWM MOSFET 60V - 200V OptiMOS™ Small Signal Non isolated PoL, Buck price/performance Low voltage overshoots enabling easy design in Industry’s lowest RDS(on) Highest system efficiency and power density Outstanding quality and reliability Reduces the need for a snubber circuit Synchronous 40V - 100V Rectification MOSFET OptiMOS™ Or-ing MOSFET 25V - 30V OptiMOS™ MOSFET 20V - 30V OptiMOS™ Small Signal Power Stage 25V - 30V DrMOS, DrBlade™ Driver and MOSFET in one package Double side cooling possibility Integrated sense feature (thermal and current) PRIMARION™ Triple-rail & multi-phase controllers with I2C/PMBus, integr. NVM Temp. range -40 to +125°C, power modes <30,<0.5,<0.2mW Integr. ARM µ-processor External temp. sense, digitally programmable PID & current balancing Active Transient Response (ATR) modulation for optimum response Digital DC/DC Controller to high di/dt load transients Since the control has a crucial role in the optimal SMPS design, Infineon also proposes families of analog (ICEXX / TDAXX families) and digital controllers (XMC family) able to meet different needs, including power management and digital communication topics. Control ICs 24 Functional Block Topology Voltage Class Technology Benefit Auxilliary Power Supply QR/FF Flyback CoolSET™ 800V ICE2QRxx80(Z)(G) ICE3xRxx80J(Z)(G) Low standby power, high efficiency PFC CCM PFC IC 800V ICE3PCS0xG High PFC, low THD PWM HB LLC IC 800V ICE1HS01G-1 ICE2HS01G High efficiency, low EMI PFC and PWM PFC/LLC/ZVS-PSF/TTF 800V XMC Flexibility, HR PWM, digital communication Applications Telecom Power Supply IGBTs For price optimization, Infineon offers two excellent alternatives. The TRENCHSTOP™ 5 technology provides outstanding performance at excellent price point which is ideal for PFC and inverter stages, addressing Gold Efficiency Standard. The TRENCHSTOP™ 5 features a very low Qg to achieve high light load efficiency. The H5 is suitable for plug & play replacement of MOSFET while F5 version is optimized for high efficiency solutions. Both the H5 and F5 include an ultra-fast discrete free-wheeling diode which has been optimized for improved ruggedness in ZVS and LLC topologies. Functional Block Topology Voltage Class Technology Benefit PFC CCM/interleaved PFC; TTF 650V TRENCHSTOP™ H5 Ease-of-use PFC CCM/interleaved PFC; TTF 650V TRENCHSTOP™ F5 High efficiency, low gate drive losses in low inductance designs PWM ZVS PS FB; LLC 650V TRENCHSTOP™ H5 Improved ruggedness and ease-of-use In cost optimized PFC, Rapid 2 diode is able to provide low Qrr and Irrm at a very attractive price. Boost Diodes Functional Block Topology Voltage Class Technology Benefit PFC CCM/interleaved PFC 650V Rapid 2 Low reverse recovery losses and PFC switch turn-on losses, common-cathode configuration Blockdiagram Analog and Digital Control ICs VBULK VIN AC AC/DC rectifier PFC Main Stage Rectification Or-ing, Hot Swap VOUT DC AUX Isolated DC/DC DC Non-Isolated PoL niPOL, Buck Power Distribution Hot Swap Hot Swap Load Rectification Load Battery Protection 25 Battery Charger E-Mobility Best Solutions for Battery Chargers To recharge the battery of an electric or hybrid/electric car, a charger is needed. Chargers can be implemented onboard or off-board the vehicle. Electric energy may be transferred to the vehicle by wire or by wireless methods like resonant inductive power transfer. Power units on-board the vehicle require automotive-grade components, while the wider product selection of industrial-grade components can be used for off-board units. On-Board Chargers In cars with On-Board Chargers the batteries can be recharged from any standard AC power outlet which provides maximum power of 3.6kW best case (single phase 230V/16A). This standard charging at low power takes several hours (overnight). Battery charging via the power grid requires a flexible power converter topology to handle different voltage and power ratings wherever the car may go to and On-Board Chargers need to be as efficient and small as possible to stay cool at lowest possible weight. Off-Board Chargers In Off-Board Chargers, the power conversion from AC grid voltage to DC battery voltage is done outside the car and the resulting DC power is transmitted by wire to the EV’s DC-charging socket. Ultra-fast chargers with power ratings at 50kW and more have been designed in this way. As the power converter is off-board, automotive grade qualification is not required for the respective electronic components. Apart from fast and ultra-fast chargers, there may be a market for Off-Board Chargers in the power range up to 10kW, for example to charge small and economic electric vehicles (LEVs). Also in case of the Off-Board Chargers, selecting the right topology to enable maximum conversion efficiency is an important design criterion. Diagram of AC/DC Battery Chargers: Functional Blocks L1 Power (Grid) L2 L3 N RFI Filter PFC DC/DC Converter RFI Filter PFC DC/DC Converter RFI Filter PFC DC/DC Converter Battery Management L1 L2 L3 Auxiliary Power Supply Microcontroller Power Supply 32-bit Microcontroller TC23xL TC26xD XMC1000* XMC4000* Transceiver *For off-board chargers onliy 26 Control + Display Isolated Current Sensor Isolation I/V Measurement Single Phase Charger Applications Wireless Chargers Product Portfolio for On-Board & Off-Board Charger Applications Infineon’s comprehensive portfolio of semiconductors (sensors, Microcontrollers, power semiconductors, etc.) lends itself perfectly to designs of compact units for on-board, off-board and wireless charging. Our products in this sector support high switching frequencies at lowest possible RDS(on) to enable compact and efficient designs : MOSFETs such as CoolMOS™ , IGBTs TRENCHSTOP™ 5 and SiC Schottky Diodes like 650V thinQ!™ SiC Diode. In addition, integrated MOSFET and IGBT drivers, controller ICs for active CCM PFC high-performance Microcontroller solutions and high accurate current sensors complete our product portfolio. Automotive Products for On-Board Units Product Family Description 1ED020I12FA2 Single-channel isolated driver for 650V/1200V IGBTs and MOSFETs Automotive EiceDRIVER™ 1ED020I12FTA Automotive EiceDRIVER™ Single-channel isolated driver, two-level turn-off for 650V/1200V IGBTs 2ED020I12FA Automotive EiceDRIVER™ Dual-channel isolated driver for 650V/1200V IGBTs and MOSFETs IPx65RxxxCFDA CoolMOS™ 650V MOSFET with integrated Fast Body Diode IKWxxN65F5A TRENCHSTOP™ 5 650V fast IGBT with Rapid 1 Diode IGWxxN65F5A TRENCHSTOP™ 5 650V fast IGBT single 32-bit lockstep Microcontroller TC23xL, TC26xD AURIX™ TLF35584 1) System Supply New ISO26262-system-supply optimized for AURIX™ TLE7250G Transceiver High-speed automotive CAN transceiver TLE6251D Transceiver High-speed automotive CAN transceiver, with wake-up Industrial Products for Off-Board Units Product Family Description IKWxxN65F5 TRENCHSTOP™ 5 650V fast IGBT with Rapid 1 Diode IGWxxN65F5 TRENCHSTOP™ 5 650V fast IGBT single IDWxxG65C5 thinQ!™ 650V SiC Schottky Diode Generation 5 IPW65RxxxC7 CoolMOS™ 650V MOSFET, C7 series for hard switching topologies HYBRIDPACK™ 1 Power Module 1200V/200A for fast & ultrafast charging (>10kW/phase) XMC1000 2), XMC4000 2) XMC Microcontroller 32-bit ARM® Cortex™ M0/M4F Microcontrollers, up to 125ºC ambient temperature (XMC4000) IFX1763, IFX54441, IFX54211 Linear Voltage Regulator Linear voltage regulator family with output current capability of 500mA/300mA/150mA respectively IFX1050, IFX1021 Transceiver High-speed CAN transceiver / LIN transceiver TLI4970 Current Sensor 600V functional isolation, ± 50A Wireless Charging Wireless methods for power transfer to charge the batteries of electric vehicles are gaining attention. Several concepts for wireless power transfer systems have been proposed, which in general seek to compensate the significant stray inductances on primary and secondary sides of the magnetic couplers by adaptive resonant methods. By the end of 2013, SAE announced a future standard for inductive charging which will define 3 power levels at 85kHz. Our TRENCHSTOP™ 5 IGBT and thinQ!™ SiC Diodes are perfectly suited for driving inductive power transfer systems (on the road side) which operate inside the 80kHz to 90kHz band. M Power (Grid) 50/60Hz ~ PFC AC/DC + Inverter - Resonance Loops ~ 85kHz Receiver ~ Resonance Loops Rectifier Road Side + - + Battery Management HV Battery - Car Side 1) in development 2) for external chargers 27 Charger Concepts Automotive Products for the Car Side Product Family Description 1ED020I12FA2 Automotive EiceDRIVER™ Single-channel isolated driver for 650V/1200V IGBTs and MOSFETs 1ED020I12FTA Automotive EiceDRIVER™ Single-channel isolated driver, two-level turn-off for 650V/1200V IGBTs 2ED020I12FA Automotive EiceDRIVER™ Dual-channel isolated driver for 650V/1200V IGBTs and MOSFETs IPx65RxxxCFDA CoolMOS™ 650V MOSFET with integrated Fast Body Diode IKWxxN65F5A TRENCHSTOP™ 5 650V fast IGBT with Rapid 1 Diode IGWxxN65F5A TRENCHSTOP™ 5 650V fast IGBT single TC23xL, TC26xD AURIX™ 32-bit lockstep Microcontroller TLF35584 1) System Supply New ISO26262-system-supply optimized for AURIX™ Industrial Products for the Road Side Product Family Description IKW40N65F5 TRENCHSTOP™ 5 Fast IGBT with Rapid 1 Diode, 40A, TO-247 IGW40N65F5 TRENCHSTOP™ 5 Fast IGBT, single, 40A, TO-247 IDW40G65C5 thinQ!™ 650V SiC Schottky Diode Generation 5, 40A, TO-247 2) XMC4000 XMC Microcontroller 32-bit ARM® Cortex™ -M4F Microcontrollers, up to 125 ºC ambient temperature IFX1763, IFX54441 Linear Voltage Regulator Linear voltage regulator family with output current capability of 500mA or 300mA respectively TLI4970 Current Sensor 600V functional isolation, +/- 50A Available in different current ratings too. Charger Concepts without Galvanic Isolation of the Power Stages Transformerless design, without galvanic isolation inside the power stages, are economic and efficient. But enhanced safety measures may be required to operate such designs from standard AC-grid power outlets. There need to be Type-B RCD (GFCI) safety switches on the grid side to immediately break the circuit in case an unintended feedback of DC-voltage from the HV-battery into the AC-grid occurs under worst case failure conditions, but Type-B safety switches on the grid side are not standard by today. This is a main reason why non-isolated designs are currently not accepted for On-Board Chargers as the level of safety-measures on the grid side of the charging spot is uncertain. However, inside an Off-Board Charger installation with an integrated Type-B safety switch, the use of non-isolated concepts may be indicated. To highlight their opportunities, Infineon has investigated non-isolated concepts, built and evaluated laboratory-demonstrators of single-phase 3kW chargers without galvanic isolation inside the power stages. L1 Power (Grid) AC/DC RCD (GFCI) Type B ~ N PFC w/o galvanic isolation + + DC/DC Buck - - To EV‘s DC Charging Socket Concept Demonstrator of Lean and Efficient Off-Board DC-Charger w/o galvanic isolation Input 230V/50Hz single phase AC Output 220V – 390VDC, max. power 3.3kW at 350V with 96.2% efficiency More detailed information about this demonstrator is available upon request. Industrial Products for the Road Side Product Family Description ICE3PCS01G Integrated controller For active CCM PFC, PG-DSO-14 IPW65R019C7 CoolMOS™ 650V MOSFET, 19mΩ, TO-247 IDW30G65C5 thinQ!™ 650V SiC Schottky Diode Generation 5, 30A, TO-247 TLI4970 Current sensor 600V functional isolation, ± 50A 1) in development 2) Automotive version under consideration 28 Applications Battery Management Best Solution for Battery Management An intelligent Battery Management System (BMS) is necessary to sustain battery performance throughout its entire lifetime - the challenge there is to tune the utilization of each battery cell individually. Passive cell balancing is the default approach where the weakest one of the cells sets the limits for battery lifetime and cruising range. Infineon’s Microcontrollers and sensors in combination with our power devices enable active cell balancing while charging and discharging. An active cell balancing system helps to increase the effective cruising range and the battery’s lifetime by 5 to 10 %, compared to passive balancing. In this context we want to mention our 8-bit XC886CM Microcontroller family for the slave blocks and the new 32-bit AURIX™ Microcontroller family for the master block, our OptiMOS™ low voltage MOSFETs, our automotive CAN transceivers TLE7250G, TLE6251D as well as step-down DC/DC controllers TLE6389-2GV and brand-new TLF35584. Main Switch Product Family Description IPx65RxxxCFDA CoolMOS™ 650V MOSFET with integrated Fast Body Diode Battery Master Description TC23xL, TC26xD New 32-bit AURIX™ lockstep Microcontroller TLF35584 1) New ISO26262-system-supply optimized for AURIX™ TLE7250G High-speed automotive CAN transceiver TLE6251D High-speed automotive CAN transceiver, with wake-up Battery Master Description XC886CM 8051 compatible 8-bit automotive Microcontroller TLE6389-2GV Step-down DC/DC controller TLE7250G High-speed automotive CAN transceiver IPG20N04S4L OptiMOS™ -T2 Power-Transistor, Logic Level, Dual, 40V/8.2mW IPD70N03S4L OptiMOS™ -T2 Power-Transistor, Logic Level, 30V/4.3mW IPD70N10S3L OptiMOS™ -T2 Power-Transistor, Logic Level, 100V/11.5mW Private CAN Battery Block Slave 8-bit µC XC 886CM 6x IPG20N04S4L-08 IPD70N03S4L IPD70N10S3L TLE7250G TLE6389-2GV Battery Master 32-bit Microcontroller TC23xL/TC26xD Public CAN TLF35584 HS-CAN Transceiver TLE7250G Battery Block Slave 8-bit µC XC 886CM 6x IPG20N04S4L-08 IPD70N03S4L IPD70N10S3L TLE7250G + Main Switch CoolMOS™ 650V 150-400V - TLE6389-2GV Battery Block Slave 8-bit uC XC 886CM 6x IPG20N04S4L-08 IPD70N03S4L IPD70N10S3L TLE7250G TLE6389-2GV 1) in development 29 Solar Solar Leading Products for Solar Power Systems Infineon provides a comprehensive portfolio to deliver the best efficiency and reliability for Solar applications. Infineon’s leading edge technology like Superjunction MOSFET, TRENCHSTOP™ and Fieldstop IGBT, Coreless transformer driver etc. combined with rich experience and highest quality, ensured our number 1 position in Solar application. The newest add ARM® Cortex™ -M4 based MCU enables easy and high efficiency design. Optimizer 250W - 750W Single/Dual Micro Inverter 250W-600W; 900W OptiMOS™ SSO8 | 60V-200V OptiMOS™ SSO8 CanPAK™ | 75V - 150V MOSFET String Inverter 1kW - 30kW CoolMOS™ D2PAK/ThinPAK 600V-800V CoolMOS™ TO-247 | 600V/650V | 19mΩ-99mΩ thinQ!™ ThinPAK/DPAK | 650V/1200V SiC Diode thinQ!™ TO-220/TO-247 | 650V/1200V IGBT TRENCHSTOP™/HighSpeed 3 600V/650V/1200V TO-247 Single/Duo Pack Power Module & Stack EasyPACK 1B/2B Press FIT Driver IGBT Driver: 1ED020I12-F2, 2ED020I12-F2 Schottky Diode BAT165 Schottky Diode Auxiliary Power Supply CoolSET™ 800V Microcontroller XMC 1xxx ARM® Cortex™-M0 XMC 1xxx ARM® Cortex™-M0 XMC 1xxx ARM® Cortex™-M0 XMC 45xx ARM® Cortex™-M4 XMC 45xx ARM® Cortex™-M4 XMC 45xx ARM® Cortex™-M4 Infineon Leading Products for Complete Solar System PV OptiMOS™* CoolMOS™ thinQ!™ Rapid Diode IGBT OptiMOS™* CoolMOS™ thinQ!™ Rapid Diode Boost DC/DC Power Module CoolMOS™ IGBT DC/AC Active Junction Box OptiMOS™ Grid EiceDRIVER™ ... Sensors EiceDRIVER™ ... EiceDRIVER™ ... PWM MPPT XMC1000/XMC4000 AURIX™ 30 Auxiliary Power Supply Applications Solar CoolMOS™ SiC Diode CoolMOS™ SiC Diode Grid CoolMOS™ SiC Diode CoolMOS™ SiC Diode OptiMOS™ PV OptiMOS™ DC 20V to 90V 45V (typ.) OptiMOS™ OptiMOS™ Micro Inverter XMC1000/XMC4000 Microcontroller Power Supply MPPT Calculation PWM Generation ADC Infineon OptiMOS™ for Micro Inverter Input Voltage Topology MOSFET Breakdown Voltage SuperSO8 Suggestion CanPAK™ Suggestion D2PAK Suggestion Up to 48V Half bridge, full bridge, LLC and other resonant 60V BSC014N06NS BSC016N06NS BSC028N06NS BSC039N06NS BSB028N06NN3G – Up to 64V Half bridge, full bridge, LLC and other resonant 80V BSC030N08NS5 BSC052N08NS5 BSB044N08NN3G – Up to 80V Half bridge, full bridge, LLC and other resonant 100V BSC035N10NS5 BSC040N10NS5 – IPB020N10N5 Up to 60V Flyback 150V BSC091N15NS5 BSC108N15NS5 BSC175N15NS5 BSB165N15NZ3 IPB041N15N5 IPB063N15N5 IPB108N15N3G Push pull 200V BSC320N20NS3G – IPB107N20N3G Recommended Infineon CoolMOS™ for Micro Inverters Topology Package Voltage Class CoolMOS™ Current source D²PAK 800V SPB17N80C3 Current / voltage source D²PAK 650V IPB65R190C6 IPB65R190C7 IPB65R125C7 IPB65R095C7 IPB65R065C7 IPB65R045C7 ThinPAK 8x8 600V IPL60R210P6 650V IPL65R195C7 IPL65R130C7 IPL65R099C7 IPL65R070C7 Recommended Infineon Microcontrollers for Micro Inverters Topology Package Voltage Class Technology Microcontroller All All XMC1000 Microcontroller Supply Linear voltage regulator Up to 20V IFX1763, IFX54441, IFX54211 Microcontroller All All XMC4000 31 Solar DC 20V to 150V 45V (typ.) OptiMOS™ OptiMOS™ Optimizer ~ DC 80V (typ.) OptiMOS™ OptiMOS™ PV XMC1000 Microcontroller Power Supply MPPT Calculation PWM Generation ADC Infineon OptiMOS™ for Optimizer DC/DC Power Conversion Input Voltage Topology MOSFET Breakdown voltage SuperSO8 Suggestion S3O8 Suggestion CanPAK™ Suggestion D2PAK and DPAK Suggestion Up to 48V Buck-boost 60V BSC016N06NS BSZ042N06NS BSB028N06NN3G IPB026N06N Up to 60V Buck-boost 75V BSC042NE7NS3G – – IPB049NE7NS3G Up to 64V Buck-boost 80V BSC027N08NS5 BSC052N08NS5 BSC117N08NS5 BSZ075N08NS5 BSZ084N08NS5 BSZ110N08NS5 BSB044N08NN3G BSF134N10NJ3G IPB017N08N5 IPB031N08N5 IPB049N08N5 Up to 80V Buck-boost 100V BSC035N10NS5 BSZ097N10NS5 BSB056N10NN3 IPB020N10N5 Up to 125V Buck-boost 200V BSC320N20NS3G BSZ900N20NS3 G – IPD320N20N3G Recommended Infineon Microcontrollers for Power Optimizers Server Power Supply Topology Voltage Class Microcontroller All All Technology XMC1000 MC Supply Linear Voltage Regulator Up to 20V IFX1763, IFX54441 Microcontroller All All XMC4000 String Inverter (Non-Isolated) Inverter CoolMOS™ < 600V DC (typ.) PV EiceDRIVER™ TRENCHSTO P™ 5/HighSpeed 3 SiC Diode/ Rapid Diode PV TRENCHSTOP™ 5/HighSpeed 3 Boost Grid Sensors EiceDRIVER™ ... ... PWM MPPT Microcontroller Power Supply 32 XMC4000 MPPT Calculation PWM Generation ADC Applications String Inverter (Three-Phase) Inverter Boost Phase C SiC Diode 1200V Phase B Phase A HighSpeed 3 1200V <1000V (typ.) TRENCHSTOP™ 5 650V HighSpeed 3 1200V PV PV 3~ Grid Grid Sensors EiceDRIVER™ EiceDRIVER™ ... ... PWM XMC4000 MPPT Microcontroller Power Supply MPPT Calculation PWM Generation ADC Infineon Discrete Power Device for String Inverter Typical Part Number Voltage Class Power Device Driving Method Voltage Class Typical Part Number CoolMOS™ CP/C7 IPW65R045C7 650V IGBT Single channel 1200V 1ED020I12-F2/B2 thinQ!™ SiC Diode IDW20G65C5 650V IGBT Half bridge 1200V 2ED020I12-FI Inverter Type Function Product Series Single Phase Boost DC/DC CoolMOS™ C6 IPW65R041C6 650V thinQ!™ SiC Diode IDW20G65C5 650V Rapid Diode IDW15E65D2 650V Inverter HighSpeed 3 Three Phase Boost Infineon EiceDRIVER™ for String Inverter IKW40N60H3 600V TRENCHSTOP™ 5 IKW40N65H5 650V CoolMOS™ C6 IPW65R041C6 650V HighSpeed 3 IKW40N120H3 1200V thinQ!™ SiC Diode IDW40G120C5B 1200V IKW40N120H3 1200V Inverter HighSpeed 3 Infineon CoolSET™ for String Inverter Voltage class Typical Part Number 800V ICE3AR2280JZ 650V ICE3BR1765JZ Recommended Infineon Microcontrollers for String Inverters Server Power Supply Topology Voltage Class Microcontroller All All Technology XMC4000 Microcontroller Supply Linear Voltage Regulator Up to 20V IFX1763, IFX54441 33 Induction Cooking Major Home Appliances Highest Performance and Efficiency for Induction Cooking Appliances Resonant-switching applications such as induction cooktops and inverterized microwave ovens have unique system requirements. The consumer market place demands that they be cost effective, energy efficient and reliable. To achieve these goals, designers need devices that are created specifically for these applications. Infineon’s RC-H family of discrete IGBTs was developed for soft switching with a monolithically integrated reverse conducting diode. With this technology leadership and a broad portfolio of devices from 650V to 1600V, it is the market leader and provides the industry benchmark performance in terms of switching and conduction losses. The newest generation in the family is the RC-H5, which extends the performance leadership for both half bridge and single ended designs. New 650V devices with higher blocking voltage offer higher reliability with improved performance even in designs which require higher frequencies or hard switching conditions. The updated RC-H5 1350V and 1200V offer the lowest switching losses across a broad range of operating conditions, allowing customers to develop the most efficient and reliable designs. Infineon also offers a range of complementary products which can be used with the IGBT, as well as in the central control and Power Supply subsystems of Induction Cooking appliances. Induction Heating Inverter (Current Resonance) Induction Heating Inverter (Voltage Resonance) Half bridge Single switch AUX Lres RC - IGBT Lres RC - IGBT VAC CK2 34 Cbus Cres Driver Cbus Cres AUX 2 RC - IGBT Driver MCU CK1 VAC Lf Cres MCU Lf 2 Induction Heating Topology Voltage Class Technology/Product Family Selection DC/AC Series resonant half bridge 650V RC-H5 Recommendation Quasi resonant single ended 1100V RC-H3 Recommendation Quasi resonant single ended 1200V & 1350V RC-H3, RC-H5 Recommendation Quasi resonant single ended 1600V RC-H2 Recommendation IGBT Driver Single channel & half bridge 600V & 1200V EiceDRIVER™ Recommendation Microcontroller - - XMC1000 Recommendation Microcontroller Supply Linear voltage regulator Up to 20V IFX54211 Efficiency AUX Flyback 650V CoolSET™ QR Efficiency Flyback 800V CoolSET™ QR Recommendation Buck Converter 800V CoolSET™ F3 Recommendation Applications Aircon Major Home Appliances Innovative Approach for Inverterized Drives Product designers are facing the daunting challenge of delivering smaller, smarter, more powerful and more energyefficient appliances. Based on industry-leading technology and manufacturing expertise, our line of innovative components for household appliances meets and exceeds even the most rigorous requirements for reliability and quality. The block diagram of an air conditioning system together with the product selection table provides effective guidelines for engineers in selecting the right component for each power management stage inside Major Home Appliances. Rectification Power Management PLUG DC Supply IGBT Driver Stage M User Interface & Communication Central Control Unit AF Discretes Sense & Monitor MCU Rotor Position Detection Aircon Topology Voltage Class Technology/Product Family Selection PFC AC/DC PFC CCM (low frequency) 600V TRENCHSTOP™ Recommendation PFC CCM (high frequency) 600V HighSpeed 3 Recommendation PFC CCM 600V CoolMOS™ P6 Reference PFC CCM 650V Rapid 1 and Rapid 2 Recommendation PFC CCM - CCM PFC Controller ICE2PCS0xG, ICE3PCS0xG Recommendation B6-VSI 600V RC-Drives IGBT Recommendation B6-VSI 600V TRENCHSTOP™ Efficiency IGBT Driver Driver for B6 bridge 600V EiceDRIVER™ (6ED) Recommendation AUX Buck converter 650V CoolSET™ F3R Recommendation Flyback 800V CoolSET™ QR Recommendation Buck converter 800V CoolSET™ F3R Recommendation - - XMC1000 Reference DC/AC Microcontroller - - XMC4000 Recommendation Microcontroller Supply Linear voltage regulator Up to 20V IFX1763, IFX54441, IFX54211 Efficiency Communication CAN, LIN transceiver - IFX1050, IFX1021 Robustness Position Sensing Angle sensor - TLE5009, TLE5012B Recommendation Hall switch - TLI496x Recommendation Angle Sensor - - TLE5009, TLE5012B Recommendation Hall Switch - - TLI496x Recommendation 35 Lighting Lighting Long Lifetime & High Efficiency for Street Lighting & High Bay Lighting Street Lighting and High Bay Lighting for warehouses, factories and other applications where high light output is required are being converted into LED Lighting very fast. Key drivers Reduction of maintenance cost of LED systems due to longer lifetime Higher efficiency of LED systems including light load condition during dimming at night Infineon’s Offering for LED Lighting Highly efficient AC/DC power conversion including light load condition Big choice of highly efficient and reliable high voltage MOSFETs Industry leading thermal protection provided by DC/DC LED driver IC’s Modularity by selecting number of LED strings Scalability by offering same footprint for different LED currents Dual-Stage PFC + LLC 60V DC/DC ILD6000 series Constant Voltage DC/DC Power Dual-Stage PFC + Flyback Single-Stage PFC/Flyback 40V DC/DC ILD4000 series Linear BCR400 series Constant Current Power Conversion AC/DC Single-Stage PFC/Flyback Buck Converter Primary stage with constant voltage output Secondary stage with constant current output Primary stage with constant current output High Voltage MOSFETs for Lighting CoolMOS™ Due to its low cost and easy implementation, Quasi-Resonant Flyback is the most commonly used topology in LED drivers. This makes CoolMOS™ 800V CE the perfect fit for this application. In addition to this, other topologies, such as fixedfrequent Flyback topology, are supported by 600V or 650V-type MOSFETs. For high-power Lighting applications, where each percentage point counts, the P6-type for high performance and low RDS(on) MOSFETs are the preferred choice. 36 Topology Voltage Class RDS(on) Selection Quasi-Resonant Flyback 800V CE 1Ω … 2.8Ω DPAK, IPAK Quasi-Resonant Flyback 800V C3 85mΩ … 0.95Ω TO-220, TO-220 FP Quasi-Resonant Flyback 900V C3 340mΩ … 1.2Ω TO-220, TO-220 FP PFC stage 600V C6 99mΩ … 600mΩ DPAK, TO-220 FP LLC stage 500V CE, 600V C6, 600V P6 190mΩ … 950mΩ DPAK, TO-220 FP Non-isolated Buck 500V CE 1Ω ... 3Ω DPAK Applications Lighting AC/DC Power Conversion (Dual Stage PFC+LLC) Application example - 110W LED driver with constant voltage output 22Ω 6 8 R30 0.82Ω R31 0.82Ω R15 470kΩ C12 2.2nF R24 10kΩ ICL5101 PFCGD HSGND PFCVS LSGD PVCCS 4 3 9 10 LSCS 11 13 R27 330Ω R26 6.2kΩ R25 6.8kΩ C13 1µF 22Ω 15 14 1 6.8kΩ D14 1N4148 22Ω 2 Details ICL5101* AC/DC off-line LED Driver IC IPD50R500CE CoolMOS™ 500V CE for LLC stage IPD60R950E6 CoolMOS™ 600V E6 for PFC stage Q3 R18 10Ω 6 L /3 5 2 C3 470µF/ 35V X1 1 2 GNDA IPD50R500CE D10 1N4148 R14 39kΩ R13 51Ω VCC R22 1.0Ω R23 1.2Ω R20 5.6Ω C11 1µF/ 50V C28 100pF R17 2.7kΩ GNDA D21 Q4 BCX70K BA885 R38 3.3kΩ D20 Key Features and Benefits of AC/DC Module ZMM15 Highest efficiency of 94% at nominal load GND Very high power factor of 99% Very low THD < 5% providing high margin to fulfill regulatory requirements Both high efficiency and low THD also at light load condition Low Bill of Material (BOM) due to –– Combo IC combining PFC and LLC in one IC –– Resistors can replace capacitors to adjust electrical parameters Part Number GND D9 BYG20J R12 R32 GND Q1 C5 100nF 2 L2/1 1 LVS HSGD HSVCC 5 C9 33µF PFCZCD C2 470µF/ 35V 7 L /4 8 2 R7 820kΩ C4 22nF/ 630V 3 L2/2 4 R6 30kΩ Q2 R9 470kΩ R10 R5 16 RES C7 D8 81M 5 C14 2.2nF/Y2 7 L1/2 4 D7 81M IPD60R950E6 IPD50R500CE RTPH F1 2 +1 2x 47mH 7 RFRUN 330nF/X2 C5 R4 820kΩ VCC 3 2 1 3 L3 +4 D4 GND 12 GND X2 MBR820H200CT D6 81M 220nF/X2 D5 81M D2 MUR160 RFPH L /1 2 1 2 1.6mH C24 1µF 4 CK1 3 C20 1nF R35 500Ω 1 C18 R39 220nF 47kΩ 2 8FH517A-3 IC2 TL431CLP R43 6.2kΩ C26 R42 33kΩ 2.2nF/Y1 GNDA * coming Q2 2015 37 Lighting DC/DC Power Conversion (60V DC/DC Buck Converter) Application Example with ILD6070/6150 with constant current output Key Features & Benefits Wide input voltage from 4.5V – 60V Scalable for an output current up to 1500mA due to same footprint –– Up to 700mA with ILD6070 in SO-8 exposed pad –– From 700mA –1500mA with ILD6150 in SO-8 exposed pad Provides both PWM or analog dimming options High efficiency of up to 98% Advanced thermal protection including –– Current reduction in a slope enables the protection of LED lifetime –– Trigger point of thermal protection can be adjusted –– No need for external NTC or PTC, thereby reducing system cost Evaluation boards available: EVALLED-ILD6150 DC/DC Power Conversion (40V DC/DC Buck Converter) Application example with ILD4001 with constant current output RSense Supply voltage VSupply ISense GND GND Schottky Diode e.g. BAS3020B L Analog voltage / digital PWM signal PWM/Enable Iout N-MOSFET e.g. BSR302N BSS306N Key Features & Benefits Wide input voltage from 4.5 - 40V Thermal protection included Coverage of wide current range from 10 - 3000mA –– No external NTC required –– Smooth reduction of LED current at high temperature level Small SC-74 package Cost can be optimized by selection of respective MOSFET –– Low cost solution with BSR302 –– Lowest cost solution with BSS306 High efficiency up to 98% 38 Evaluation boards available: ILD4001 1A Applications Industrial Welding Industrial Welding (MMA < 280A) Innovative Solutions for Your Applications In the field of Industrial Welding machines, discrete IGBTs are used in small inverterized 1-phase hand-held welders from 120A to 200A and 3-phase welding machines with up to 300A Iout for industrial use. With the trend towards higher switching frequency, Infineon’s portfolio perfectly supports customer requirements by offering 600V, 650V and 1200V discrete IGBTs at an excellent performance/price point. For 2015, the new WR5 series based on the TRENCHSTOP™ 5 technology will be released, specifically for the price sensitive 1-phase welding machine market to offer a new benchmark in performance/price. The WR5 offers low switching losses coupled with low conduction losses plus excellent Rg controllability to provide customers with improved efficiency and outstanding thermal behavior. Meanwhile for the Best-in-Class performance, where customers are striving for differentiation in the welding market, the H5 series offers the highest efficiency for optimized designs. Excellent dynamic response of the H5 series enables the arc-current to be reached in a shorter time contributing to better weld quality. Additionally, in-house application tests have shown the case temperature of the H5 to be 20% lower than the next Best-in-Class competitor device. For 3-phase welders, Infineon’s 1200V H3 family is the market’s preferred device, due to its outstanding efficiency and controllability. Full bridge / Half bridge 4x HighSpeed IGBT Two Transistor Forward 2x HighSpeed IGBT AC Output (Al/Mg welding) Diode IGBT IGBT Diode IOUT IGBT Diode LOUT Diode VIN IGBT VIN Diode LOUT Diode IGBT IGBT IGBT IOUT Diode Diode IGBT Diode Diode Diode Diode IGBT IGBT IGBT IGBT PFC Diode IGBT Diode Diode Industrial Welding Topology Voltage Class Technology/Product Family Selection DC/AC Full bridge/half bridge/TTF 650V WR5 TRENCHSTOP™ 5 Recommendation Full bridge/half bridge 650V TRENCHSTOP™ 5 Recommendation Full bridge/half bridge/TTF 1200V HighSpeed 3 Recommendation Two Transistor Forward 650V Rapid 1/Rapid 2 Recommendation Boost converter/switch 650V WR5 TRENCHSTOP™ 5 Recommendation Boost converter/switch 650V TRENCHSTOP™ 5 Reference Boost converter/switch 1200V HighSpeed 3 Reference Boost converter/diode 650V Rapid 1/Rapid 2 Recommendation Half bridge single channel 600V/1200V EiceDRIVER™ (1ED) Efficiency Half bridge dual channel 600V/1200V EiceDRIVER™ (2ED) Recommendation Boost converter 650V CoolSET™ F3 Recommendation Boost converter - XMC1000 Flexibility Linear voltage regulator Up to 20V IFX54211 Efficiency AC/DC: PFC IGBT Driver Controller Microcontroller Supply 39 Battery Powered Applications Battery Powered Applications Highest Performance in your Drives Application Based on industry leading technology, the highest quality and manufacturing expertise, Infineon provides a variety of innovative power semiconductors which enable designers to develop highly reliable and efficient solutions for all kinds of drive applications. Key enabling products Low voltage power MOSFETs – OptiMOS™ Small Signal products High voltage power MOSFETs – CoolMOS™ Gate drivers – EiceDRIVER™ Compact Microcontrollers and supply – XMC and voltage regulators Magnetic sensors Infineon offers a comprehensive portfolio to address a broad range of Battery Powered Motor Control applications such as Forklift, E-Scooter, Pedelecs, Low Speed Cars and many others. For further information please explore our homepage. Infineon Solution Tree for Battery Powered Applications Cordless Tools Light Electric Vehicle OptiMOS™ 20V-80V MOSFET Forklift OptiMOS™ 60V-150V Small Signal (SOT-363, TSOP-6) Driver ICs EiceDRIVER™ Compact (2EDL23N06) EiceDRIVER™ Compact (2EDL05N06, 6EDL04N02PR, 6ED003L02-F2) Microcontroller XMC4000 XMC1000 Microcontroller Supply IFX1763, IFX54441 IFX54211 Magnetic Hall Sensors Hall Sensors Angle Sensors Linear Hall Sensors 40 Applications Battery Powered Applications Typical Low Voltage Application: Battery Powered 3-Phase System Power Management Battery Management CoolMOS™ DC/DC Linear Voltage Regulators OptiMOS™ Gate Driver EiceDRIVER™ 3-Phase Bridge Drive Status Indication LED Drivers ≤ 60V User Interface 3-Phase Inverter M OptiMOS™ XMC Microcontroller XMC1000 XMC4000 USB, Serial COM & Ethernet Hall Switch Linear Hall Sensors Angle Sensors Current Sensors Current Sensing Position Sensing To shorten customer development cycle time and cost we offer a complete portfolio of low voltage motor control application kits: XMC1000 Motor Control Application Kit XMC4000 Motor Control Application Kit 300W Motor Control Application Kit Evaluation Board 5kW TO-Leadless 1kW Motor Control Application Kit www.infineon.com/motorcontrolapplicationkit www.infineon.com/to-leadless-evaluationboard 41 Light Electric Vehicles Light Electric Vehicles Leading-Edge Innovation, Outstanding Reliability and Excellent Quality Infineon’s solutions for Light Electric Vehicles provide leading-edge innovation, outstanding reliability and excellent quality. We offer the full range of semiconductor solutions – from low voltage power MOSFETs to Microcontrollers. Key requirements for those applications like E-Bikes, Pedelecs, E-Scooters, Low Speed Cars, Forklifts, etc. are increasing the range of the vehicle, increasing battery lifetime and reducing charging time. Infineon offers the right set of devices for battery management and voltage regulation with highest possible efficiency. Besides power management, the power consumption is effectively controlled by XMC controllers, EiceDRIVER™ gate drivers, OptiMOS™ low voltage MOSFETs. Key Enabling Products for Light Electric Vehicles are: Low voltage power MOSFETs – OptiMOS™ High voltage power MOSFETs – CoolMOS™ Gate drivers – EiceDRIVER™ Compact Microcontrollers and supply – XMC and voltage regulators, DC/DC converters Silicon Power Diodes – Rapid 1 and Rapid 2 Diode Magnetic Sensors Application Requirements Efficiency: reduction of overall system energy consumption, increasing the battery lifetime Reliability: reliable operation and avoiding system down time Maintenance: low maintenance and long lifetime of components Size and Cost: reduction of overall system size and cost Time to market: reduction of development time and cost Benefits of Infineon Components Complete portfolio from one source Increased lifetime due to Infineon reliability and quality Smallest area for highest power density BOM cost reduction due to lowest RDS(on) Complete support infrastructure: simulations, documentation and demoboards Power MOSFETs Microcontroller 42 Driver ICs Magnetic Sensors Applications Light Electric Vehicles Application Diagram of Infineon Solution for Inverter and Charger Charger CoolMOS™ OptiMOS™ Control ICs for PWM & PFC DC/DC converters Linear voltage regulators Microcontroller XMC4000 family XMC1000 family Charger 24V/36V/48V/72V 110V/230V AC/DC Battery DC/DC Gate Driver EiceDRIVER™ 3-Phase Bridge Drive XMC Microcontroller XMC1000 XMC4000 User Interface & Communication 3-Phase Inverter M OptiMOS™ USB, Serial COM & Ethernet Sense & Monitor Current & Position Sensing Angle sensors Hall switches Current sensor Recommended Products for Inverter Battery Voltage Low Voltage MOSFETs Standard Solution High End Solutions 24V IPD034N06N3 G BSC028N06NS 36V IPD053N08N3 G BSC047N08NS3 G 48V IPP045N10N3 G IPB042N10N3 G IPT020N10N3 2EDL05N06PF Gate Driver - EiceDRIVER™ Microcontroller - XMC XMC1302 XMC4400 Microcontroller Supply Linear Voltage Regulator (IFX54211) DC/DC Converter (IFX90121) Linear Voltage Regulator (IFX1763, IFX54441) DC/DC Converter (IFX90121, IFX91041) Hall Switch (TLI496x) Angle Sensor (TLE5009, TLE5012B) Current & Position Sensors Current Sensor (TLI4970) Communication IFX1050G Recommended Products for LEV Charger Battery Voltage 600V High Voltage MOSFETs AC/DC (PFC) IPP60R125P6 IPP60R160P6 IPP60R190P6 IPL60R180P6 650V Low Voltage MOSFETs Diodes Synchronous Rectification OptiMOS™ in TO-220, SuperSO8 or D²PAK 40V - 100V 650V DC/DC (PWM) IPP60R099C6 IPP60R125C6 IPP60R160C6 IPP60R190C6 IPP65R110CFD IPP65R150CFD IPL65R165CFD IPP65R190CFD IPL65R210CFD Rapid Diodes in TO-220 43 Wireless Power Wireless Power Highest Efficiency for Wireless Charging Now is the time when Wireless Power applications will enter the main stream. We will each have one or more applications of Wireless Charging in our daily lives in the coming years, starting with battery charging of Mobile Devices. That is on top of the electric toothbrush that seems to be around forever. A typical wireless power transfer system consists of the AC/DC Adapter powering the charging station or mat, the transmitter in the station or mat and the receiver which usually is highly integrated and embedded in the mobile device or the back cover of a Smartphone. Infineon’s CoolSET™ series continues to deliver design agility and miniaturization. For example the F3 series combines a new feature-packed controller with the power of CoolMOS™ to give you the output power you desire. Alternatively a stand-alone PWM IC (Fix Frequency or Quasi Resonant) can be combined with a discrete 600V/650V CoolMOS™ C6 available in different packages including DPAK, IPAK and the newest ThinPAK 5x6. Especially for emerging higher power (10W+) transmitter applications equipping your half or full bridge with components from the OptiMOS™ 30V product family with their ultralow gate and output charge, together with lowest on-state resistance in small footprint packages will pay off with superior power transfer performance. There are Half Bridge modules, dual N-Channel and single N-Channel OptiMOS™ versions available for your Wireless Power transmitter design. AC Supply 12~20V Transmitter (Tx) Coils HB/FB Driver CoolSET™ Digital Control PWM+COM 44 2-4x LV MOS OptiMOS™ AC/DC Adapter Receiver (RX) embedded in mobile system (eg: Smartphone) AC/DC Adapter Description ICE3ARXX65JG CoolSET™ F3 series with integrated switch for Fixed Frequency Flyback ICE2QRXX65G CoolSET™ F3 series with integrated switch for Quasi Resonant Flyback ICE3BS03LJG Stand-alone PWM IC for Fixed Frequency Flyback ICE2QS03G Stand-alone PWM IC for Quasi Resonant Flyback IPL65R1K5C6S 650V CoolMOS™ MOSFET in ThinPAK 5x6 IPD65R1K4C6 650V CoolMOS™ MOSFET in DPAK IPU60R1K4C6 600V CoolMOS™ MOSFET in IPAK Transmitter Description XMC 1302 or XMC 4108 32-bit XMC Microcontroller (XMC 1302 for single standard, XMC 4108 for multi standard solution) BSC0925ND 5x6 OptiMOS™ 30V/5mΩ half bridge Module SuperSO8 BSC150N03LDG OptiMOS™ 3 Dual N-Channel, Logic Level, 30V/15mΩ SuperSO8 BSC072N03LDG OptiMOS™ 3 Dual N-Channel, Logic Level, 30V/7.2mΩ SuperSO8 BSZ065N03LS OptiMOS™ Power MOSFET, Logic Level, 30V/6.5mΩ S3O8 BSC0909NS OptiMOS™ Power MOSFET, Logic Level, 34V/9.2mΩ SuperSO8 BSC120N03MSG OptiMOS™ 3 Power MOSFET, Logic Level 5V opt., 30V/12mΩ SSO8 Application Support Expert Support for Applications Easy Access and High Quality Block Diagrams, Documents, Videos, Evaluation Boards & More www.infineon.com/smps www.infineon.com/emobility www.infineon.com/solar www.infineon.com/industrial www.infineon.com/consumer www.infineon.com/lighting www.infineon.com/motorcontrol www.infineon.com/automation Applications 45 OptiMOS™ OptiMOS™ Leading-Edge Solutions Infineon’s innovative products serve the market needs throughout the whole energy supply chain. OptiMOS™ is the market leader in highly efficient solutions for power generation (e.g. Solar Micro Inverter), Power Supply (e.g. Server and Telecom) and power consumption (e.g. Electric Vehicle). In all these areas, engineers face the challenges of growing power demand, increasing efficiency and lowering cost. At the same time, the available space is constantly shrinking, leading to higher power density requirements. The solution can be found with Infineon's power MOSFET OptiMOS™ family. From 20V up to 300V, OptiMOS™ consistently sets the benchmark in key specifications for power system design. Leading on-state resistance and Figure of Merit characteristics enable reduced power losses and improved overall efficiency. Lower power losses enable system cost improvement by reducing the need for device paralleling and allowing smaller heatsinks. The OptiMOS™ family also provides the opportunity for more compact Power Supply designs. Available in innovative space saving packages such as TO-Leadless, CanPAK™ , SuperSO8 or S3O8, power stage and Blade, these products reduce area consumption. TO-Leadless for example, allows a 60% space reduction compared to D2PAK 7pin. In addition, TO-Leadless improves switching noise and EMI for SMPS, as well as for other industrial applications. OptiMOS™ Products are Suitable for a Wide Range of Applications: VR-modules for Server Solar Micro Inverter and Maximum Power Synchronous rectification for AC/DC SMPS Point Tracker (MPPT) DC/DC converters LED Lighting Motor Control 12V-110V systems Notebook and Desktop 80 RDS(on) [mΩ] @ 10V in SuperSO8 RDS(on) [mΩ] @ 10V in SuperSO8 4 3 2 1 0 60 40 20 0 25 30 Infineon 40 Voltage Class [V] 60 Next Best Competitor 75 80 100 120 150 200 250 Voltage Class [V] Infineon Next Best Competitor Demonstrating > 93% Efficiency in Voltage Regulation for Power Applications With the new OptiMOS™ 25V and 30V product family, Infineon sets new standards in power density and Energy Efficiency for discrete power MOSFETs and system in package. Ultra low gate and output charge, together with lowest on-state resistance in small footprint packages, make OptiMOS™ 25V the best choice for the demanding requirements of voltage regulator solutions in Servers, Datacom and Telecom applications. OptiMOS™ 30V products are tailored to the needs of power management in Notebook by improved EMI behavior, as well as increased battery life. 46 LV – OptiMOS™ OptiMOS™ With the New OptiMOS™ Products, We Have the Best Solution to: Save overall system costs by reducing the number of phases in multiphase converters Reduce power losses and increase efficiency for all load conditions Save space with the smallest packages such as CanPAK™, S3O8 or system-in-package solution Minimize EMI in the system making external snubber networks obsolete and the products easy to design-in Efficiency [%] Efficiency of OptiMOS™ 25V in a Six-Phase Server VRD 96 94 92 90 88 86 84 82 80 78 76 74 72 70 Outstanding performance of the new OptiMOS™ 25V and 30V products is exemplified on a six-phase Server Vcore VRD. 93% peak efficiency and >90% full load efficiency is demonstrated with the new OptiMOS™ 25V products in SuperSO8 package. (high side: BSC050NE2LS; low side: BSC010NE2LS) Vin = 12V, Vout = 1.2V Lout = 210nH, Vdrive = 5V 0 20 40 60 80 100 120 140 160 180 Output Current [A] fswitch = 350kHz fswitch = 500kHz Clean Waveforms for Optimized EMI Behavior Make New OptiMOS™ 25V/30V Products Easy to Use Voltage across Sync Fet [V] 17.5 15.0 Vin = 12V, Vdrive = 5V, Iout = 20V 12.5 10.5 7.5 5.0 2.5 With the new OptiMOS™ 25V/30V products short switching times (rise and fall times <5ns) go in hand with excellent EMI behavior. An integrated damping network guarantees low over and undershoot and minimizes ringing without sacrificing efficiency. 0 -2.5 -5.0 0 100 200 300 400 500 600 700 800 900 1000 Time [ns] 47 OptiMOS™ Packages Always a Step Ahead with Infineon With OptiMOS™ 40V-300V products, we set the benchmark in the industry. The leading on-state resistance (RDS(on)) and switching behavior reduce power losses and enable overall efficiency of 96%. With these products Infineon supports the market trend towards Energy Efficiency targets such as Energy Star Titanium Level. OptiMOS™ technology enables for the first time very low RDS(on) values needed for high current applications in space saving packages such as SuperSO8, S3O8 and CanPAK™ and TO-Leadless, which were previously only possible in bulky packages. Efficiency 96 Using Infineon products in Synchronous Rectification of a 600W Server Power Supply with 12V output brings your peak efficiency 0.3% higher. 95 Efficiency [%] 94 93 92 91 90 89 88 150 200 250 300 350 400 450 500 550 600 Output power [W] Competitor BSC016N06NS TO-Leadless TO-Leadless package is especially designed for high current applications with high power and reliability requirements such as Forklift, Light Electric Vehicles, e-fuse, PoL (Point of Load) and Telecom. The outstanding current capability up to 300A is an ideal feature for these applications. Furthermore, TO-Leadless offers benefits in terms of optimized board space. The significantly smaller package size, reduced by 60%, enables a very compact design. Compared to D2PAK 7pin, TO-Leadless shows a 30% reduction in Optimized for High Power Applications footprint. This allows a board space reduction in Forklift applications and the 50% reduced height offers a significant advantage in narrow applications such as rack or blade Servers. DrBlade™ The Revolutionary Next Packaging Generation 48 DrBlade™ is the new ultra-compact integrated MOSFET half bridge with driver, realized in a revolutionary new packaging technology. It is an ideal solution for buck converter applications with highest efficiency and power density requirements. The Blade packaging technology realizes a low package resistance and inductance as well as high current handling capability. It replaces standard packaging processes such as bonding or molding which provide a 30% package footprint reduction. Additionally, the thermal resistances to the package bottom and top side are optimized, improving its thermal behavior. The new packaging technology is available in discrete products such as in the integrated DrBlade™ configuration including driver and MOSFETs. OptiMOS™ Packages In applications like Synchronous Rectification in Server and Desktop, Motor Drives and DC/DC converters in Telecom, high power density and high efficiency are the major driving factors. The trend set by Infineon to move from TO-220 to SuperSO8 in Server reduces the area consumption drastically. With three times lower resistance parasitic compared to TO-220, SuperSO8 offers highest efficiency and lowest design efforts due to reduced spikes. LV – OptiMOS™ SuperSO8/S3O8 The Intelligent Way to Highest Efficiency and Power Density CanPAK™ The CanPAK™ portfolio is the best fit for a broad number of industrial applications such as voltage regulator for Servers, DC/DC converters in Telecom, Solar Micro Inverters and Maximum Power Point Trackers (MPPT), low voltage drives and Synchronous Rectification in server and desktop. With only a 31mm² footprint, CanPAK™ M allows 79% space reduction in power components on the board compared to traditional D2PAK. In addition, the metal ‘Can’ enables double-sided cooling along with almost no package parasitic inductances, leading to a higher systems efficiency. Best Thermal Behavior in a Tiny Footprint Power stage 3x3 and power stage 5x6 Dual FET power stages in a single leadless SMD package integrate the low side and high side MOSFET of a synchronous DC/DC converter into a 3x3mm2 or 5x6mm2 package outline. Designers are able to shrink their designs up to 85% by replacing two separate discrete packages such as SO-8 or SuperSO8 with this new package. Both the small outline and the interconnection of the two MOSFETs within the package minimize the loop inductance which boosts efficiency. With the new OptiMOS™ technology, power stage 3x3 and power stage 5x6 achieve a peak efficiency of 93.5%. Power stage 3x3 can handle an application current up to 12.5A and power stage 5x6 up to 30A. Save Space, Minimize Losses, Boost Efficiency Small Signal Small Signal MOSFETs from Infineon are available in 7 industry-standard package types ranging from the largest SOT-223 down to the smallest SOT-363 measuring 2.1mm x 2mm x 0.9mm. Products are offered in single, dual and complementary configurations and are suitable for a wide range of applications including Battery Protection, LED Lighting, low voltage drives and DC/DC converters. All Infineon Small Signal packages are qualified to Automotive AEC Q101. Automotive Qualified Packages 49 OptiMOS™ Product Table OptiMOS™ 20V Super Logic Level RDS(on) max @VGS=4.5V [mΩ] TO-251 / TO-251 SL TO-252 (DPAK) CanPAK™ S/M TO-263 (D2PAK 7pin) TO-220 TO-220 FullPAK SuperSO8 SO-8 BSC019N02KS G <2 RDS(on)= 1.9mΩ BSC026N02KS G 2-4 RDS(on)=2.6mΩ BSC046N02KS G 4-10 RDS(on)=4.6mΩ OptiMOS™ 25V Logic Level RDS(on) max @VGS=10V [mΩ] <1.0 1-2 TO-251 / TO-251 SL TO-252 (DPAK) CanPAK™ S/M BSB008NE2LX TO-263 (D2PAK 7pin) TO-220 TO-220 FullPAK SuperSO8 S3O8 BSC009NE2LS RDS(on)= 0.8mΩ RDS(on)=0.9mΩ BSB012NE2LX BSC010NE2LS RDS(on)=1.2mΩ RDS(on)=1.0mΩ BSB012NE2LXI BSC010NE2LSI RDS(on)=1.2mΩ RDS(on)=1.05mΩ BSB013NE2LXI BSC014NE2LSI RDS(on)=1.3mΩ RDS(on)=1.4mΩ BSC018NE2LS BSZ18NE2LS RDS(on)=1.8mΩ RDS(on)=1.8mΩ BSC018NE2LSI BSZ018NE2LSI RDS(on)=1.8mΩ RDS(on)=1.8mΩ BSC024NE2LS RDS(on)=2.4mΩ 2-4 BSF030NE2LQ 1) BSC032NE2LS RDS(on)=3.0mΩ RDS(on)=3.2mΩ BSF035NE2LQ 1) RDS(on)=3.5mΩ 4-6 BSZ036NE2LS RDS(on)=3.6mΩ BSC050NE2LS RDS(on)=5.0mΩ BSZ060NE2LS RDS(on)=6.0mΩ 6-7 1) 50 CanPAK™ S LV – OptiMOS™ OptiMOS™ Product Table OptiMOS™ 25/30V in power stage 3x3 and 5x6 Part Number Monolithically integrated Schottky like diode BVDSS (V) RDS(on)max. [mΩ] @ VGS=4.5V max Qg [nC] @ VGS=4.5V typ High Side Low Side High Side Low Side BSC0910NDI 25 5.9 1.6 7.7 25.0 BSC0911ND – 25 4.8 1.7 7.7 25.0 BSC0921NDI 30 7.0 2.1 5.8 21.0 BSC0923NDI 30 7.0 3.7 5.2 12.2 BSC0924NDI 30 7.0 5.2 5.2 8.6 BSC0925ND – 30 6.4 6.4 5.2 6.7 BSG0811ND - 25 4 1.1 5.6 20 BSG0813NDI 25 4 1.7 5.6 12 51 OptiMOS™ Product Table OptiMOS™ 30V Logic Level RDS(on) max @VGS=10V [mΩ] TO-251 / TO251 SL TO-252 (DPAK) CanPAK™ M TO-Leadless TO-263 (D2PAK) TO-263 (D2PAK 7pin) TO-220 SuperSO8 S3O8 Bare Die (RDS(on) typ.) BSB012N03LX3 G IPT004N03L IPB009N03L G BSC011N03LS IPC218N03L3 RDS(on)=1.2mΩ RDS(on)=0.95mΩ RDS(on)=1.1mΩ RDS(on)=0.5mΩ RDS(on)=0.4mΩ BSC011N03LSI RDS(on)=1.1mΩ BSC014N03LS G RDS(on)=1.4mΩ 1-2 BSB017N03LX3 G BSC016N03LS G BSZ019N03LS IPC055N03L3 RDS(on)=1.7mΩ RDS(on)=1.6mΩ RDS(on)=1.7mΩ RDS(on)=1.9mΩ BSC0901NS RDS(on)=1.9mΩ BSC0901NSI BSZ0901NS RDS(on)=2.0mΩ RDS(on)=2.0mΩ BSC020N03LS G BSZ0901NSI IPC042N03L3 RDS(on)=2.0mΩ RDS(on)=2.3mΩ RDS(on)=2.1mΩ BSC025N03LS G RDS(on)=2.5mΩ 2-4 BSC0902NS BSZ0902NS RDS(on)=2.6mΩ RDS(on)=2.6mΩ BSC0902NSI BSZ0902NSI RDS(on)=2.8mΩ RDS(on)=2.8mΩ IPS031N03L G IPD031N03L G IPB034N03L G IPP034N03L G BSC030N03LS G BSZ035N03LS G RDS(on)=3.1mΩ RDS(on)=3.1mΩ RDS(on)=3.4mΩ RDS(on)=3.4mΩ RDS(on)=3.0mΩ RDS(on)=3.5mΩ BSC034N03LS G RDS(on)=3.4mΩ BSC0904NSI RDS(on)=3.7mΩ IPS040N03L G IPD040N03L G IPB042N03L G IPP042N03L G BSC042N03LS G BSZ0904NSI RDS(on)=4.0mΩ RDS(on)=4.0mΩ RDS(on)=4.2mΩ RDS(on)=4.2mΩ RDS(on)=4.2mΩ RDS(on)=4.0mΩ BSC0906NS RDS(on)=4.5mΩ 4-6 IPS050N03L G IPD050N03L G RDS(on)=5.0mΩ RDS(on)=5.0mΩ BSC050N03LS G BSZ050N03LS G IPC028N03L3 RDS(on)=5.0mΩ RDS(on)=5.0mΩ RDS(on)=5.0mΩ IPB055N03L G IPP055N03L G BSC052N03LS IPC022N03L3 RDS(on)=5.5mΩ RDS(on)=5.5mΩ RDS(on)=5.2mΩ RDS(on)=5.3mΩ BSC057N03LS G BSZ058N03LS G RDS(on)=5.7mΩ 6-8 RDS(on)=5.8mΩ IPS060N03L G IPD060N03L G IPB065N03L G BSZ065N03LS RDS(on)=6.0mΩ RDS(on)=6.0mΩ RDS(on)=6.5mΩ RDS(on)=6.5mΩ IPS075N03L G IPD075N03L G IPB080N03L G RDS(on)=7.5mΩ RDS(on)=7.5mΩ RDS(on)=8.0mΩ BSC080N03LS G BSZ088N03LS G RDS(on)=8.0mΩ 8-10 IPS090N03L G IPD090N03L G RDS(on)=9.0mΩ RDS(on)=9.0mΩ RDS(on)=8.8mΩ BSC090N03LS G RDS(on)=9.0mΩ BSC0909NS RDS(on)=9.2mΩ BSZ100N03LS G RDS(on)=10.0mΩ BSC120N03LS G BSZ0909NS 10-15 2 x 7.2 2 x 15 50 52 RDS(on)=12.0mΩ RDS(on)=12.0mΩ IPD135N03L G BSZ130N03LS G RDS(on)=13.5mΩ RDS(on)=13.0mΩ BSC072N03LD G RDS(on)=7.2mΩ BSC150N03LD G RDS(on)=15.0mΩ IPC014N03L3 RDS(on)=50.0mΩ LV – OptiMOS™ OptiMOS™ Product Table OptiMOS™ 30V Logic Level 5V Optimized RDS(on) max @VGS=10V [mΩ] TO-251 / TO-251 SL TO-252 (DPAK) TO-263 (D2PAK) TO-263 (D2PAK 7pin) TO-220 TO-220 FullPAK SuperSO8 S3O8 SO-8 BSC014N03MS G <2 RDS(on)=1.4mΩ BSC016N03MS G RDS(on)=1.6mΩ BSC020N03MS G BSZ035N03MS G BSO033N03MS G RDS(on)=2.0mΩ RDS(on)=3.5mΩ RDS(on)=3.3mΩ BSC025N03MS G BSO040N03MS G RDS(on)=2.5mΩ RDS(on)=4.0mΩ BSC030N03MS G 2-6 RDS(on)=3.0mΩ BSC042N03MS G BSZ050N03MS G RDS(on)=4.2mΩ RDS(on)=5.0mΩ BSC050N03MS G BSZ058N03MS G RDS(on)=5.0mΩ RDS(on)=5.8mΩ BSC057N03MS G RDS(on)=5.7mΩ 6-10 BSC080N03MS G BSZ088N03MS G RDS(on)=8.0mΩ RDS(on)=8.8mΩ BSC090N03MS G RDS(on)=9.0mΩ BSC100N03MS G BSZ100N03MS G BSO110N03MS G 10-20 RDS(on)=10.0mΩ RDS(on)=10.0mΩ RDS(on)=11.0mΩ BSC120N03MS G BSZ130N03MS G RDS(on)=12.0mΩ RDS(on)=13.0mΩ >20 2x15 2x22 BSO150N03MD G RDS(on)=15.0mΩ BSO220N03MD G RDS(on)=22.0mΩ 53 OptiMOS™ Product Table OptiMOS™ 40V Logic Level/Normal Level RDS(on) max @VGS=10V [mΩ] TO-252 (DPAK) CanPAK™ S/M TO-263 (D2PAK) TO-263 (D2PAK 7pin) TO-220 TO-220 FullPAK SuperSO8 S3O8 Bare Die (RDS(on) typ.) BSC010N04LS RDS(on)=1.0mΩ BSC010N04LSI RDS(on)=1.05mΩ BSC014N04LS RDS(on)=1.4mΩ BSC014N04LSI RDS(on)=1.45mΩ BSB014N04LX3 G <2 IPB015N04N G IPB011N04L G IPP015N04N G RDS(on)=1.5mΩ BSC016N04LS G RDS(on)=1.4mΩ RDS(on)=1.5mΩ RDS(on)=1.1mΩ BSB015N04NX3 G IPB015N04L G IPB011N04N G BSC017N04NS G RDS(on)=1.6mΩ RDS(on)=1.5mΩ RDS(on)=1.5mΩ RDS(on)=1.1mΩ RDS(on)=1.7mΩ BSC018N04LS G IPC218N04N3 RDS(on)=1.8mΩ RDS(on)=0.5mΩ BSC019N04NS G IPC171N04N RDS(on)=1.9mΩ RDS(on)=1.1mΩ BSC019N04LS RDS(on)=1.4mΩ 2-3 IPB020N04N G IPP023N04N G BSC022N04LS BSZ023N04LS RDS(on)=2.0mΩ RDS(on)=2.3mΩ RDS(on)=2.2mΩ RDS(on)=2.3mΩ IPB023N04N G BSC026N04LS BSZ028N04LS RDS(on)=2.3mΩ RDS(on)=2.6mΩ RDS(on)=2.8mΩ BSC027N04LS G RDS(on)=2.7mΩ BSC030N04NS G RDS(on)=3.0mΩ 3-4 4-7 IPD036N04L G IPP039N04L G BSC032N04LS BSZ034N04LS RDS(on)=3.6mΩ RDS(on)=3.9mΩ RDS(on)=3.2mΩ RDS(on)=3.4mΩ BSC035N04LS G BSZ040N04LS G RDS(on)=3.5mΩ RDS(on)=4.0mΩ IPP041N04N G BSC050N04LS G BSZ042N04NS G RDS(on)=4.1mΩ RDS(on)=5.0mΩ RDS(on)=4.2mΩ IPP048N04N G BSC054N04NS G RDS(on)=4.8mΩ RDS(on)=5.4mΩ BSC059N04LS G RDS(on)=5.9mΩ 7-8 8-10 10-11 BSC093N04LS G RDS(on)=9.3mΩ BSZ097N04LS G RDS(on)=9.7mΩ BSZ105N04NS G RDS(on)=10.5mΩ BSZ165N04NS G 13-17 54 RDS(on)=16.5mΩ OptiMOS™ 60V Logic Level/Normal Level RDS(on) max @VGS=10V [mΩ] TO-252 (DPAK) CanPAK™ S/M TO-Leadless TO-262 (I2PAK) TO-263 (D2PAK) TO-263 (D2PAK 7pin) TO-220 TO-220 FullPAK SuperSO8 IPD025N06N 2) BSB028N06NN3 G IPT007N06N 2) IPI020N06N 2) IPB019N06L3 G IPB010N06N 2) IPP020N06N 2) IPA029N06N 2) BSC014N06NS 2) RDS(on)=2.5mΩ RDS(on)=2.8mΩ RDS(on)=2.0mΩ RDS(on)=1.9mΩ RDS(on)=1.0mΩ RDS(on)=2.0mΩ RDS(on)=2.9mΩ RDS(on)=1.4mΩ <3 RDS(on)=0.7mΩ Bare Die (RDS(on) typ.) IPI024N06N3 G IPB014N06N 2) IPP024N06N3 G BSC016N06NS 2) IPC218N06L3 RDS(on)=2.4mΩ RDS(on)=1.4mΩ RDS(on)=2.4mΩ RDS(on)=1.6mΩ RDS(on)=1.2mΩ IPI029N06N 2) IPB026N06N 2) IPB016N06L3 G IPP029N06N 2) BSC028N06NS 2) IPC218N06N3 RDS(on)=2.9mΩ RDS(on)=2.6mΩ RDS(on)=1.6mΩ RDS(on)=2.9mΩ RDS(on)=2.8mΩ RDS(on)=1.3mΩ IPB029N06N3 G IPB017N06N3 G BSC028N06LS3 G RDS(on)=2.9mΩ RDS(on)=1.7mΩ RDS(on)=2.8mΩ IPD031N06L3 G IPI032N06N3 G IPB034N06L3 G RDS(on)=3.1mΩ RDS(on)=3.2mΩ IPD034N06N3 G RDS(on)=3.4mΩ 3-5 S3O8 IPP032N06N3 G IPA032N06N3 G BSC031N06NS3 G BSZ042N06NS 2) RDS(on)=3.4mΩ RDS(on)=3.2mΩ RDS(on)=3.2mΩ RDS(on)=3.1mΩ IPB037N06N3 G IPP037N06L3 G IPA040N06N 2) BSC034N06NS2) RDS(on)=3.7mΩ RDS(on)=3.7mΩ RDS(on)=4.0mΩ RDS(on)=3.4mΩ IPI040N06N3 G IPP040N06N 2) BSC039N06NS 2) RDS(on)=4.0mΩ RDS(on)=4.0mΩ RDS(on)=3.9mΩ IPD038N06N3 G IPP040N06N3 G RDS(on)=3.8mΩ RDS(on)=4.0mΩ RDS(on)=4.2mΩ IPD048N06L3 G RDS(on)=4.8mΩ IPD053N06N 2) RDS(on)=5.3mΩ 5-7 IPP052N06L3 G IPA057N06N3 G BSC066N06NS2) RDS(on)=6.6mΩ RDS(on)=5.2mΩ RDS(on)=5.7mΩ IPB057N06N 2) IPP057N06N3 G IPA060N06N 2) BSC067N06LS3 G BSZ067N06LS3 G RDS(on)=5.7mΩ RDS(on)=5.7mΩ RDS(on)=6.0mΩ RDS(on)=6.7mΩ RDS(on)=6.7mΩ BSZ068N06NS2) IPP060N06N 2) RDS(on)=6.0mΩ 7-10 IPD079N06L3 G IPI084N06L3 G IPB081N06L3 G RDS(on)=7.9mΩ RDS(on)=8.4mΩ RDS(on)=6.8mΩ IPP084N06L3 G IPA093N06N3 G BSC076N06NS3 G BSZ076N06NS3 G RDS(on)=9.3mΩ RDS(on)=7.6mΩ RDS(on)=8.1mΩ RDS(on)=8.4mΩ IPD088N06N3 G IPB090N06N3 G IPP093N06N3 G BSC097N06NS 2) BSZ100N06LS3 G RDS(on)=8.8mΩ RDS(on)=9.0mΩ RDS(on)=9.3mΩ RDS(on)=9.7mΩ RDS(on)=10.0mΩ BSC100N06LS3 G BSZ100N06NS 2) RDS(on)=10.0mΩ RDS(on)=10.0mΩ 11-30 RDS(on)=7.6mΩ BSF110N06NT3 G1) BSC110N06NS3 G BSZ110N06NS3 G RDS(on)=11.0mΩ RDS(on)=11.0mΩ RDS(on)=11.0mΩ IPD350N06L G RDS(on)=35.0mΩ 30-50 IPD400N06N G RDS(on)=40.0mΩ IPD640N06L G RDS(ON = 64.0mΩ 1) 2) CanPAK™ S 6V rated (RDS(on) also specified @ VGS=6V) 55 LV – OptiMOS™ OptiMOS™ Product Table OptiMOS™ Product Table OptiMOS™ 75V Normal Level RDS(on) max @VGS=10V [mΩ] TO-252 (DPAK) CanPAK™ S/M TO-262 (I2PAK) TO-263 (D2PAK) 2-4 4-6 TO-263 (D2PAK 7pin) TO-220 TO-220 FullPAK SuperSO8 S3O8 Bare Die (RDS(on) typ.) IPB020NE7N3 G IPP023NE7N3 G BSC036NE7NS3 G IPC302NE7N3 RDS(on)=2.0mΩ RDS(on)=2.3mΩ RDS(on)=3.6mΩ RDS(on)=1.2mΩ IPB031NE7N3 G IPP034NE7N3 G RDS(on)=3.1mΩ RDS(on)=3.4mΩ IPB049NE7N3 G IPP052NE7N3 G BSC042NE7NS3 G RDS(on)=4.9mΩ RDS(on)=5.2mΩ RDS(on)=4.2mΩ IPP062NE7N3 G 6-12 RDS(on)=6.2mΩ BSF450NE7NH3 1) 12-45 RDS(on)=45.0mΩ OptiMOS™ 80V Normal Level 2) RDS(on) max @VGS=10V [mΩ] TO-252 (DPAK) CanPAK™ S/M TO-Leadless TO-262 (I2PAK) TO-263 (D2PAK 7pin) TO-220 TO-220 FullPAK SuperSO8 IPT012N08N5 IPB017N08N5 IPB015N08N5 IPP020N08N5 RDS(on)=1.2mΩ RDS(on)=1.7mΩ RDS(on)=1.5mΩ RDS(on)=2.0mΩ IPB025N08N3 G IPB019N08N3 G IPP023N08N5 IPA028N08N3 G BSC026N08NS5 RDS(on)=2.5mΩ RDS(on)=1.9mΩ RDS(on)=2.3mΩ RDS(on)=2.8mΩ RDS(on)=2.6mΩ 1-3 3-4 TO-263 (D2PAK) RDS(on)=1.2mΩ IPP027N08N5 BSC030N08NS5 RDS(on)=2.0mΩ RDS(on)=2.7mΩ RDS(on)=3.0mΩ IPP028N08N3 G RDS(on)=2.4mΩ RDS(on)=2.8mΩ IPI037N08N3 G IPB031N08N5 IPB030N08N3 G IPP034N08N5 IPA037N08N3 G BSC037N08NS5 RDS(on)=3.7mΩ RDS(on)=3.1mΩ RDS(on)=3.0mΩ RDS(on)=3.4mΩ RDS(on)=3.7mΩ RDS(on)=3.7mΩ IPB035N08N3 G IPP037N08N3 G BSC040N08NS5 RDS(on)=3.5mΩ RDS(on)=3.7mΩ RDS(on)=4.0mΩ IPD053N08N3 G BSB044N08NN3 G IPB049N08N5 IPP052N08N5 IPA057N08N3 G BSC047N08NS3 G RDS(on)=5.3mΩ RDS(on)=4.4mΩ RDS(on)=4.9mΩ RDS(on)=5.2mΩ RDS(on)=5.7mΩ RDS(on)=4.7mΩ 4-6 IPB054N08N3 G IPP057N08N3 G BSC052N08NS5 RDS(on)=5.4mΩ RDS(on)=5.7mΩ RDS(on)=5.2mΩ BSC057N08NS3 G RDS(on)=5.7mΩ BSC061N08NS5 RDS(on)=6.1mΩ IPB067N08N3 G 6-7 7-11 BSC072N08NS5 RDS(on)=6.7mΩ RDS(on)=7.2mΩ IPD096N08N3 G BSB104N08NP3 IPP100N08N3 G IPA100N08N3 G BSC117N08NS5 BSZ075N08NS5 RDS(on)=9.6mΩ RDS(on)=10.4mΩ RDS(on)=9.7mΩ RDS(on)=10.0mΩ RDS(on)=11.7mΩ RDS(on)=7.5mΩ BSZ084N08NS5 RDS(on)=8.4mΩ BSZ110N08NS5 11-20 RDS(on)=11.0mΩ IPD135N08N3 G RDS(on)=13.5mΩ 30-40 1) 2) 56 CanPAK™ S 6V rated (RDS(on) also specified @ VGS = 6V) Bare Die (RDS(on) typ.) IPC302N08N3 IPB020N08N5 IPB024N08N5 S3O8 BSC123N08NS3 G BSZ123N08NS3 G RDS(on)=12.3mΩ RDS(on)=12.3mΩ BSC340N08NS3 G BSZ340N08NS3 G RDS(on)=34.0mΩ RDS(on)=34.0mΩ LV – OptiMOS™ OptiMOS™ Product Table OptiMOS™ 100V Normal Level RDS(on) max @VGS=10V [mΩ] TO-252 (DPAK) CanPAK™ S/M 1-3 TO-Leadless TO-262 (I2PAK) TO-263 (D2PAK) TO-220 TO-220 FullPAK SuperSO8 S3O8 Bare Die (RDS(on) typ.) IPT015N10N5 2) IPB020N10N5 2) IPB017N10N5 2) IPP023N10N5 2) IPC302N10N3 RDS(on)=1.5mΩ RDS(on)=2.0mΩ RDS(on)=1.7mΩ RDS(on)=3.0mΩ RDS(on)=1.7mΩ IPT020N10N3 2) IPI030N10N3 G IPB027N10N3 G IPB025N10N3 G IPP030N10N3 G IPA030N10N3 G RDS(on)=2.0mΩ RDS(on)=3.0mΩ RDS(on)=2.7mΩ RDS(on)=2.5mΩ RDS(on)=3.0mΩ RDS(on)=3.0mΩ IPB027N10N5 2) IPP030N10N5 2) RDS(on)=2.7mΩ RDS(on)=3.0mΩ 3-4 4-6 TO-263 (D2PAK 7pin) BSC035N10NS5 2) IPC26N10NR RDS(on)=3.5mΩ RDS(on)=3.2mΩ IPB039N10N3 G BSC041N10NS5 2) IPC173N10N3 RDS(on)=3.9mΩ RDS(on)=4.1mΩ RDS(on)=3.6mΩ BSB056N10NN3 G IPI045N10N3 G IPB042N10N3 G IPP045N10N3 G IPA045N10N3 G BSC046N10NS3 G RDS(on)=5.6mΩ RDS(on)=4.5mΩ RDS(on)=4.2mΩ RDS(on)=4.5mΩ RDS(on)=4.5mΩ RDS(on)=4.6mΩ IPD068N10N3 G IPI072N10N3 G RDS(on)=6.8mΩ RDS(on)=7.2mΩ BSC060N10NS3 G RDS(on)=6.0mΩ 6-8 IPP072N10N3 G BSC070N10NS3 G RDS(on)=7.2mΩ RDS(on)=7.0mΩ BSC070N10NS5 2) RDS(on)=7.0mΩ IPD082N10N3 G IPI086N10N3 G IPB083N10N3 G IPP083N10N5 2) RDS(on)=8.2mΩ RDS(on)=8.6mΩ RDS(on)=8.3mΩ RDS(on)=8.3mΩ IPA083N10N5 2) RDS(on)=8.3mΩ IPA086N10N3 G RDS(on)=8.6mΩ 8-12 BSC098N10NS5 2) RDS(on)=9.8mΩ IPP086N10N3 G BSC109N10NS3 G BSZ097N10NS5 2) RDS(on)=8.6mΩ RDS(on)=10.9mΩ RDS(on)=9.7mΩ BSC118N10NS G RDS(on)=11.8mΩ 12-18 IPD122N10N3 G BSF134N10NJ3 G 1) IPB123N10N3 G IPP126N10N3 G IPA126N10N3 G BSZ160N10NS3 G RDS(on)=12.2mΩ RDS(on)=13.4mΩ RDS(on)=12.3mΩ RDS(on)=12.6mΩ RDS(on)=12.6mΩ RDS(on)=16.0mΩ BSC160N10NS3 G RDS(on)=16.0mΩ 18-20 IPD180N10N3 G IPI180N10N3 G IPP180N10N3 G IPA180N10N3 G BSC196N10NS G RDS(on)=18.0mΩ RDS(on)=18.0mΩ RDS(on)=18.0mΩ RDS(on)=18.0mΩ RDS(on)=19.6mΩ IPD25CN10N G 2) 20-40 RDS(on)=25.0mΩ IPD33CN10N G 1) RDS(on)=33.0mΩ BSC440N10NS3 G BSZ440N10NS3 G 40-80 RDS(on)=44.0mΩ RDS(on)=44.0mΩ IPD78CN10N G 1) RDS(on)=78.0mΩ BSC750N10ND G 2 x 75 1) 2) RDS(on)=75.0mΩ CanPAK™ S 6V rated (RDS(on) also specified @ VGS = 6V) 57 OptiMOS™ Product Table OptiMOS™ 100V Logic Level RDS(on) max @VGS=10V [mΩ] TO-251 / TO-251 SL TO-252 (DPAK) CanPAK™ M CanPAK™ S TO-262 (I2PAK) TO-263 (D2PAK) TO-263 (D2PAK 7pin) TO-220 TO-220 FullPAK SuperSO8 S3O8 Bare Die (RDS(on) typ.) 4-6 6-8 BSC082N10LS G RDS(on)=8.2mΩ BSC105N10LSF G 8-12 RDS(on)=10.5mΩ IPP12CN10L G RDS(on)=12.0mΩ BSC123N10LS G BSZ150N10LS3 IPC045010N3 RDS(on)=12.3mΩ 12-18 RDS(on)=15.0mΩ RDS(on)=15.2mΩ IPC020N10L3 RDS(on)=42.0mΩ 20-40 BSC265N10LSF G RDS(on)=26.5mΩ OptiMOS™ 120V Normal Level RDS(on) max @VGS=10V [mΩ] TO-251 / TO-251 SL TO-252 (DPAK) TO-262 (I2PAK) <4 TO-263 (D2PAK) IPB038N12N3 G IPB036N12N3 G RDS(on)=3.8mΩ RDS(on)=3.6mΩ IPI041N12N3 G RDS(on)=4.1mΩ 4-5 TO-263 (D2PAK 7pin) TO-220 SuperSO8 S3O8 Bare Die (RDS(on) typ.) IPC302N12N3 RDS(on)=2.6mΩ IPP041N12N3 G IPC26N12N RDS(on)=4.1mΩ RDS(on)=3.0mΩ IPP048N12N3 G RDS(on)=4.8mΩ 7-8 10-13 13-20 20-25 58 IPS110N12N3 G IPD110N12N3 G RDS(on)=11.0mΩ RDS(on)=11.0mΩ IPI076N12N3 G IPP076N12N3 G BSC077N12NS3 G RDS(on)=7.6mΩ RDS(on)=7.6mΩ RDS(on)=7.7mΩ IPP114N12N3 G RDS(on)=11.4mΩ IPI147N12N3 G IPB144N12N3 G IPP147N12N3 G BSC190N12NS3 G RDS(on)=14.7mΩ RDS(on)=14.4mΩ RDS(on)=14.7mΩ RDS(on)=19.0mΩ BSZ240N12NS3 G IPC300N15N3R RDS(on)=24.0mΩ RDS(on)=4.9mΩ LV – OptiMOS™ OptiMOS™ Product Table OptiMOS™ 150V Normal Level 4) RDS(on) max @VGS=10V [mΩ] TO-252 (DPAK) CanPAK™ M 3-7 TO-Leadless TO-262 (I2PAK) TO-220 TO-220 FullPAK SuperSO8 S3O8 Bare Die (RDS(on) typ.) IPT039N15N53) IPI046N15N53) IPB043N15N53) IPB040N15N53) IPP046N15N53) IPC302N15N3 RDS(on)=4.6mΩ RDS(on)=4.3mΩ RDS(on)=4.0mΩ RDS(on)=4.6mΩ RDS(on)=4.9mΩ IPB065N15N53) IPB065N15N3 G RDS(on)=5.9mΩ RDS(on)=6.5mΩ RDS(on)=6.5mΩ IPI069N15N53) IPB072N15N3 G IPP068N15N53) IPA075N15N3 G RDS(on)=6.5mΩ BSC093N15NS53) RDS(on)=6.9mΩ RDS(on)=7.2mΩ RDS(on)=6.8mΩ IPI075N15N3 G IPB108N15N3 G IPP075N15N3 G IPA105N15N3 G BSC110N15NS53) RDS(on)=7.5mΩ RDS(on)=10.8mΩ RDS(on)=7.5mΩ RDS(on)=11mΩ IPI111N15N3 G RDS(on)=11.1mΩ IPD200N15N3 G BSB165N15NZ3 G IPB200N15N3 G IPP200N15N3 G RDS(on)=20.0mΩ RDS(on)=20.0mΩ RDS(on)=20.0mΩ RDS(on)=16.5mΩ RDS(on)=10.5mΩ RDS(on)=9.3mΩ IPP111N15N3 G RDS(on)=11.1mΩ 16-30 TO-263 (D2PAK 7pin) RDS(on)=3.9mΩ IPT059N15N3 7-12 TO-263 (D2PAK) BSC160N15NS53) BSZ300N15NS53) RDS(on)=16.0mΩ RDS(on)=30mΩ BSC190N15NS3 G BSB280N15NZ3 G RDS(on)=28.0mΩ RDS(on)=19.0mΩ BSC360N15NS3 G 30-60 RDS(on)=36.0mΩ IPD530N15N3 G IPI530N15N3 G IPB530N15N3 G IPP530N15N3 G BSC520N15NS3 G BSZ520N15NS3 G RDS(on)=53.0mΩ RDS(on)=53.0mΩ RDS(on)=53.0mΩ RDS(on)=53.0mΩ RDS(on)=52.0mΩ 80-90 3) 4) RDS(on)=52.0mΩ BSZ900N15NS3 G RDS(on)=90.0mΩ In development 8V rated (RDS(on) also specified @ VGS=8V) 59 OptiMOS™ Product Table OptiMOS™ 200V Normal Level RDS(on) max @VGS=10V [mΩ] TO-252 (DPAK) TO-262 (I2PAK) TO-263 (D2PAK) TO-263 (D2PAK 7pin) TO-220 TO-220 FullPAK SuperSO8 S3O8 Bare Die (RDS(on) typ.) IPC300N20N3 RDS(on)=9.2mΩ IPI110N20N3 G RDS(on)=11.0mΩ 10-20 30-40 IPB107N20N3 G IPP110N20N3 G IPC302N20N3 RDS(on)=9.2mΩ RDS(on)=10.7mΩ RDS(on)=11.0mΩ IPB107N20NA 5) IPP110N20NA 5) RDS(on)=10.7mΩ RDS(on)=11.0mΩ IPB117N20NFD IPP120N20NFD RDS(on)=11.7mΩ RDS(on)=12.0mΩ IPD320N20N3 G IPI320N20N3 G IPB320N20N3 G IPP320N20N3 G BSC320N20NS3 G RDS(on)=32.0mΩ RDS(on)=32.0mΩ RDS(on)=32.0mΩ RDS(on)=32.0mΩ RDS(on)=32.0mΩ BSC500N20NS3G 40-50 RDS(on)=50.0mΩ 80-100 100-200 200-300 BSC900N20NS3 G BSZ900N20NS3 G RDS(on)=90.0mΩ RDS(on)=90.0mΩ BSC12DN20NS3 G BSZ12DN20NS3 G RDS(on)=125.0mΩ RDS(on)=125.0mΩ BSC22DN20NS3 G BSZ22DN20NS3 G RDS(on)=225.0mΩ RDS(on)=225.0mΩ OptiMOS™ 250V Normal Level RDS(on) max @VGS=10V [mΩ] TO-252 (DPAK) TO-262 (I2PAK) TO-263 (D2PAK) TO-263 (D2PAK 7pin) TO-220 TO-220 FullPAK SuperSO8 S3O8 IPC302N25N3A 5) 10-20 RDS(on)=16.0mΩ 20-30 IPI200N25N3 G IPB200N25N3 G IPP200N25N3 G IPC045N25N3 RDS(on)=20.0mΩ RDS(on)=20.0mΩ RDS(on)=20.0mΩ RDS(on)=25.0mΩ IPP220N25NFD RDS(on)=22.0mΩ 60-70 IPD600N25N3 G IPI600N25N3 G IPB600N25N3 G IPP600N25N3 G BSC600N25NS3 G RDS(on)=60.0mΩ RDS(on)=60.0mΩ RDS(on)=60.0mΩ RDS(on)=60.0mΩ RDS(on)=60.0mΩ 100-200 400-500 5) 60 Bare Die (RDS(on) typ.) Part qualified according to AEC Q101 BSC16DN25NS3 G BSZ16DN25NS3 G RDS(on)=165.0mΩ RDS(on)=165.0mΩ BSZ42DN25NS3 G RDS(on)=425.0mΩ LV – OptiMOS™ OptiMOS™ Product Table OptiMOS™ 300V Normal Level RDS(on) max @VGS=10V [mΩ] 40-50 TO-252 (DPAK) TO-262 (I2PAK) TO-263 (D2PAK) TO-263 (D2PAK 7pin) TO-220 IPB407N30N IPP410N30N RDS(on)=40.7mΩ RDS(on)=41.0mΩ TO-220 FullPAK SuperSO8 S3O8 Bare Die (RDS(on) typ.) 61 OptiMOS™ Product Table Small Signal Voltage [V] SOT-223 TSOP-6 SOT-89 SC-59 SOT-23 SOT-323 SOT-363 BSP317P - 250 4Ω, -0.43A, LL BSP92P BSS192P BSR92P 12Ω, -0.26A, LL 12Ω, -0.19A, LL 11Ω, -0.14A, LL BSP321P 900mΩ, -0.98A, NL - 100 BSP322P 800mΩ, -1.0A, LL BSP316P BSR316P 1.8Ω, -0.68A, LL 1.8Ω, -0.36A, LL BSP612P 120mΩ, 3A, LL - 60 BSP613P BSS83P 130mΩ, 2.9A, NL 2Ω, -0.33A, LL BSP170P BSS84P BSS84PW 300mΩ, -1.9A, NL 8Ω, -0.17A, LL 8Ω, -0.15, LL P-Channel MOSFETs BSP171P 300mΩ, -1.9A, LL BSP315P BSR315P 800mΩ, -1.17A, LL - 30 - 20 800mΩ, -0.62A, LL BSL303SPE BSR303PE 1) ~30mΩ, ~-6.6A, LL ~30mΩ, ~-3.3A, LL BSL305SPE BSR305PE 1) ~50mΩ, ~-5.3A, LL ~50mΩ, ~-2.7A, LL BSL307SP BSS308PE 43mΩ, -5.5A, LL 80mΩ, -2.1A, LL, ESD BSL308PE BSS314PE 80mΩ, -2.1A, LL, dual, ESD 140mΩ, -1.5A, LL, ESD BSL314PE BSS315P 140mΩ, -1.5A, LL, ESD, dual 150mΩ, -1.5A, LL 140mΩ, -1.5A, LL, ESD BSS356PWE 1) BSD356PE 1) ~560mΩ, ~0.73A, LL ~560mΩ, ~0.73A, LL BSL207SP BSS209PW BSV236SP 41mΩ, -6A, SLL 550mΩ, -0.58A, SLL 175mΩ, -1.5A, SLL BSL211SP BSS223PW BSD223P 67mΩ, -4.7A, SLL 1.2Ω, -0.39A, SLL 1.2Ω, -0.39A, SLL, dual BSS215P 150mΩ, -1.5A, SLL 1) Coming Q2 2015 All products are qualified to Automotive AEC Q101 62 BSD314SPE LV – OptiMOS™ OptiMOS™ Product Table Small Signal Complementary Voltage [V] -20/20 SOT-223 TSOP-6 SOT-89 SC-59 SOT-23 SOT-323 SOT-363 BSL215C BSD235C N: 140mΩ, 1.5A, SLL P: 150mΩ, -1.5A, SLL N: 350mΩ, 0.95A, SLL P: 1.2Ω, -0.53A, SLL BSL316C -30/30 N: 160mΩ, 1.4A, LL P: 150mΩ, -1.5A, LL BSL308C BSD356C 1) N: 57mΩ, A, LL P: 80mΩ, A, LL, N: 350mΩ, 0.95A, LL P: ~560mΩ, ~0.73A, LL 2) Coming Q2 2015 All products are qualified to Automotive AEC Q101 63 OptiMOS™ Product Table Small Signal Voltage [V] SOT-223 N-Channel MOSFETs 20 30 TSOP-6 SOT-89 SC-59 BSL802SN BSR802N 22mΩ, 7.5A, ULL 23mΩ, 3.7A, ULL BSL202SN BSR202N BSS806NE 22mΩ, 7.5A, SLL 21mΩ, 3.8A, SLL 57mΩ, 2.3A, ULL, ESD BSS806N BSD816SN 57mΩ, 2.3A, ULL 160mΩ, 1.4A, ULL BSL205N BSS205N BSD214SN 50mΩ, 2.5A, SLL, dual 50mΩ, 2.5A, SLL 140mΩ, 1.5A, SLL BSL207N BSS816NW BSD840N 70mΩ, 2.1A, SLL, dual 160mΩ, 1.4A, ULL 400mΩ, 0.88A, ULL, dual BSL214N BSS214N BSS214NW BSD235N 140mΩ, 1.5A, SLL, dual 140mΩ, 1.5A, SLL 140mΩ, 1.5A, SLL 350mΩ, 0.95A, SLL, dual BSL302SN BSR302N BSS306N 25mΩ, 7.1A, LL 23mΩ, 3.7A, LL 57mΩ, 2.3A, LL BSL306N BSS316N BSD316SN 57mΩ, 2.3A, LL, dual 160mΩ, 1.4A, LL 160mΩ, 1.4A, LL BSS670S2L 650mΩ, 0.54A, LL BSP318S BSL606SN BSS606N BSR606N BSS138N BSS138W 90mΩ, 2.6A, LL 60mΩ, 4.5A, LL 60mΩ, 3.2A, LL 60mΩ, 2.3A, LL 3.5Ω, 0.23A, LL 3.5Ω, 0.28A, LL BSS7728N 120mΩ, 2.9A, NL 5Ω, 0.2A, LL BSP295 SN7002N SN7002W 300mΩ, 1.8A, LL 5Ω, 0.2A, LL 5Ω, 0.23A, LL 2N7002 2N7002DW 3Ω, 0.3A, LL 3Ω, 0.3A, LL, dual BSS159N 8Ω, 0.13A, depl. BSP716N BSL716SN 160mΩ, 2.3A, LL 150mΩ, 2.5A, LL All products are qualified to Automotive AEC Q101 (except 2N7002) 64 SOT-363 57mΩ, 2.3A, ULL, dual BSP320S 75 SOT-323 BSL806N 55 60 SOT-23 OptiMOS™ Product Table Voltage [V] 100 SOT-223 TSOP-6 SOT-89 SC-59 SOT-23 BSP373N BSL373SN BSS169 240mΩ, 1.8A, NL 230mΩ, 2.0A, NL 12Ω, 0.09A, depl. BSP372N 230mΩ, 1.8A, LL BSL372SN 220mΩ, 2.0A, LL BSS119N 6Ω, 0.19A, LL VGS(th) 1.8V to 2.3V BSP296N BSL296SN 600mΩ, 1.2A, LL 460mΩ, 1.4A, LL SOT-323 LV – OptiMOS™ Small Signal SOT-363 BSS123N 6Ω, 0.19A, LL VGS(th) 0.8V to 1.8V BSP297 200 1.8Ω, 0.66A, LL BSP149 N-Channel MOSFETs 3.5Ω,0.14 A, depl. 240 BSP88 BSS87 BSS131 6Ω, 0.35A, 2.8V rated 6Ω, 0.26A, LL 14Ω, 0.1A, LL BSP89 6Ω, 0.35A, LL BSP129 6Ω, 0.05A, depl. BSS139 250 30Ω, 0.03A, depl. BSP179 24Ω, 0.20A, depl.* 400 BSP298 3Ω, 0.5A, NL BSP324 25Ω, 0.17A, LL 500 600 800 BSP299 4Ω, 0.4A, NL BSP125 BSS225 BSS127 45Ω, 0.12A, LL 45Ω, 0.09A, LL 500Ω, 0.023A, LL BSP135 BSS126 60Ω, 0.02A, depl. 700Ω, 0.007A, depl. BSP300 20Ω, 0.19A, NL * In development All products are qualified to Automotive AEC Q101 65 OptiMOS™ Product Table Power P-Channel MOSFETs RDS(on) @ VGS=10V TO-220 TO-252 (DPAK) TO-263 (D2PAK) 30mΩ BSO207P H (dual) 45mΩ BSO211P H (dual) 67mΩ BSC030P03NS3 G 3mΩ IPD042P03L3 G 4,2mΩ SPD50P03L G 1) * IPD068P03L3 G 5-7mΩ BSC060P03NS3E G BSO080P03NS3 G BSO080P03NS3E G BSO080P03S H BSO301SP H ~8mΩ P-Channel MOSFETs S3O8 BSO203SP H BSO203P H (dual) 21mΩ - 30V SuperSO8 BSO201SP H 7mΩ - 20V SO-8 BSC080P03LS G BSC084P03NS3 G BSC084P03NS3E G BSZ086P03NS3 G BSZ086P03NS3E G BSZ120P03NS3 G BSZ120P03NS3E G 12mΩ BSO130P03S H 13mΩ BSC130P03LS G BSZ180P03NS3 G BSZ180P03NS3E G 18mΩ BSO200P03S H BSO303SP H 20mΩ BSO303P H (dual) 21mΩ 1,2Ω 23mΩ SPP80P06P H * SPD30P06P G * 75mΩ - 60V 130mΩ SPP18P06P H * 210mΩ - 100V 240mΩ SPP08P06P H * SPD08P06P G * SPP15P10PL H * SPD15P10PL G * SPP15P10P H * SPD15P10P G * SPB18P06P G * BSO613SPV G * SPB08P06P G * SPD04P10PL G * 850mΩ SPD04P10P G * 1Ω Comp. SPD18P06P G * SPD09P06PL G * 250mΩ 300mΩ SPB80P06P G * BSO612CV G * -60/ 60V 11-30mΩ BSO615C G * Power P-Channel MOSFETs Comp. RDS(on) @ VGS=4.5V -20V/ 20V TO-220 55150mΩ 1) 5-leg * Products are qualified to Automotive AEC Q101 66 TO-252 (DPAK) TO-263 (D2PAK) SO-8 SuperSO8 S3O8 BSZ15DC02KD H* OptiMOS™ Nomenclature LV – OptiMOS™ Naming System OptiMOSTM BSC 014 Package Type BSB = CanPAK™ (M Can) BSC = SuperSO8 BSF = CanPAK™ (S Can) BSO = SO-8 BSZ = S3O8 SPA/IPA = FullPAK SPB/IPB = D2PAK SPC/IPC = Chip Product SPD/IPD = DPAK SPI/IPI = I2PAK SPP/IPP = TO-220 SPS/ IPS = IPAK Short Leads SPT/IPT = TO-Leadless RDS(on) [mΩ] Divide by 10 to get RDS(on) value e.g. 014 = 1.4mΩ However, if the sixth character is a C, the fourth and the fifth character indicate the RDS(on) e.g. 12C=12mΩ For chip products chip area in mm2 multiplied by 10 N = N-Channel P = P-Channel C = Complementary Breakdown Voltage [V] Multiply by 10 to get voltage class e.g. 03 = 30V E = Extended, +5V, e.g. E2 = 25V N 03 L S X E G RoHS compliant Features F = Fast switching R = Integrated gate resistor E = ESD protection A = Qualified according to AECQ101 3 = Technology generation I = Monolithically integrated Schottky like diode FD = Fast Diode Package Options SO-8/SuperSO8/S3O8 S = Single chip D = Dual chip CanPAK™ X = MX footprint N = MN footprint Z = MZ footprint Q = SQ footprint T = ST footprint H = SH footprint J = SJ footprint Level N = Normal Level M = Logic Level 5V opt. L = Logic Level K = Super Logic Level J = Ultra Logic Level (NL) (LL) (ELL) (SLL) (ULL) to be used from VGS 10.0 4.5 4.5 2.5 1.8 67 OptiMOS™ Nomenclature New OptiMOSTM 30V BSC N 0901 X I I = Monolithically integrated Schottky like diode Package Type Consecutively Number without any correlation to product specification D = Dual E = ESD S = Single Channels N = N-Channel P = P-Channel Small Signal BSX 68 J1 Y J2 Z “X” indicates the Package D = SOT-363 P = SOT-223 R = SC59 S = SOT-89, SOT-23, SOT-323 L = TSOP-6 Additional Features E = ESD protected MOSFET 3 digits product identifier meaning dependent on product generation Only present in following case W = to distinguish SOT-323 from SOT-23 Only present in following case S = Single (only for packages which are also used for multichip products) Polarity N = N-Channel P = P-Channel C = Complementary (N-Ch + P-Ch) OptiMOS™ Support Expert Support for OptiMOS™ Easy Access and High Quality Application Notes, Datasheets & More www.infineon.com/optimos-lowvoltage www.infineon.com/optimos-mediumvoltage www.infineon.com/smallsignal www.infineon.com/pchannel www.infineon.com/depletion www.infineon.com/complementary Latest Videos www.infineon.com/mediacenter Low Voltage Evaluation Boards www.infineon.com/motorcontrolapplicationkit www.infineon.com/to-leadless-evaluationboard www.infineon.com/1kw-bldc-evaluationboard Datasheets 69 CoolMOS™ CoolMOS™ Continuous Leadership in High Voltage MOSFETs The revolutionary CoolMOS™ power family sets new standards in the field of Energy Efficiency. Our CoolMOS™ products offer a significant reduction of conduction, switching and driving losses and enable high power density and efficiency for superior power conversion systems. Especially, the latest state-of-the-art generation of high voltage power MOSFETs makes AC/DC Power Supplies more efficient, more compact, lighter and cooler than ever before. Each application has its own requirements and optimization criteria which are reflected in the available technologies paired with innovative package solutions. Driving factors like efficiency, power density, controllability, EMI, layout resistance, commutation behavior and cost can not be fulfilled at the same time and leading to different technologies and solutions. For instance, high full load efficiency can be the focus. This can be achieved with lower RDS(on), yet at a higher cost. The patented TO-247 4pin package using the Kelvin source concept helps to decrease the feedback inductance. This leads to lower switching losses for free and enables better gate drive and lower RFI at the same time. A further design consideration is the handling of worst case conditions. The associated high dv/dt can trigger oscillations especially if the layout can not be optimized for the device behavior. Technologies like C6, E6, P6, CFD2 and the recently released CE series take this into account with intrinsic patented damping circuits that come without penalty in efficiency. At the same time the commutation behavior at commutation on the intrinsic body diode is improved, which enables resonant topologies. Best Solutions for Challenges Within Your Applications EMI: Higher efficiency leads to faster switching slopes and can not be optimized from technology point of view. Using fast parts the layout must be optimized by avoiding large areas in commutation and gate loops. Secondly parasitic should be minimized. This can be easily done via bifilar arrangements and small capacitive coupling areas on jumping potentials including coupling capacitances of magnetics. We have developed an in-depth understanding of these topics and our engineers are happy to support your design. Efficiency: Reflects the switching and gate drive losses. In hard switch topologies like PFC the turn-off and turn-on losses and in soft switched only the turn-off losses are reflected. Commutation: Reflects the behavior at hard commutation on the body diode. The intrinsic damping circuits or reverse recovery charge reduction lowers the overvoltage spike in the current cut-off phase. Controllability: Describes the layout resistance. Especially under worst case conditions high dv/dt and di/dt can be achieved. A good controllability is achieved if the part is limiting actively the slopes. Our nomenclature guides through different optimization criteria and will help to select and find the perfect matching part for your application. 70 HV – CoolMOS™ CoolMOS™ High Power SMPS In high power SMPS, we recommend the following products for Server, Telecom, TV, PC Silverbox and Solar applications: CoolMOS™ P6: Superior efficiency combined with ease-of-use and low design-in effort. P6 is recommended for most designs in high power SMPS applications (100W … 3kW) as an “all-rounder” part with excellent performance. The P6 is suitable for both soft and hard switching applications due to its good body diode ruggedness. High efficiency well ahead of competitor products in both PFC and LLC completes its performance. CoolMOS™ C7: Best-in-Class efficiency and fastest switching performance in the industry. The C7 is a part optimized for the highest efficiency and for higher power density designs. For example, at 45mΩ the C7 allows for > 0.7% higher light load efficiency than CoolMOS™ CP. Low Power SMPS In low power SMPS, we recommend the following products for Smartphone/Tablet Chargers, Notebook Adapters and TV sets: CoolMOS™ C6/ E6: Good efficiency, excellent ease-of-use and excellent EMI performance make C6/E6 the product of choice for many low power applications such as flyback-based Adapters and also PFC and LLC. It’s switching behavior makes it a product of choice for fast design-in when better switching performance (and price) than the predecessor CoolMOS™ C3 is needed. CoolMOS™ CE: Product for lower switching frequencies or higher transformer coupling capacitances. This technology comes ahead with smoother waveforms, lesser dv/dt, a higher internal gate resistor and even better EMI. Offers better efficiency and thermal behavior than standard MOSFET. CoolMOS™ C3: For 800V and 900V, we recommend the well-established CoolMOS™ C3 800V and C3 900V. 71 CoolMOS™ P6 CoolMOS™ P6 Series Superior Efficiency Combined with Ease-of-Use 600V CoolMOS™ P6 is Infineon's answer to SMPS applications that require excellent performance yet also a high level of ease-of-use in the design-in process. P6 is suitable for both soft and hard switching applications due to its good body diode ruggedness. Optimizations such as Qg, Vth, Eon, and Eoff enable its superior efficiency, while its ease-of-use feature is attributed to the optimized dv/dt (di/dt) controllability, internal Rg, and improved oscillation behavior. P6 achieves very low conduction and switching losses especially in light load condition enabling switching applications to work more efficient and be designed more compact, lighter and cooler. Moreover, with its granular portfolio, P6 addresses the specific needs of applications such as Server, PC Power, Telecom rectifiers and Consumer applications meanwhile offers the best price/ performance ratio on the market today. Features Reduced gate charge (Qg) Optimized Vth for soft switching Good body diode ruggedness Optimized integrated Rg Improved dv/dt Benefits Improved efficiency in light load condition Better efficiency in soft switching applications due to earlier turn-off Suitable for hard- and softswitching topologies Excellent ease-of-use and good controllability of switching behavior High robustness, better efficiency Outstanding quality and reliability Figure of Merit (Conduction loss x switching loss) Ease-of-Use Focus Balance Techno logy tre nd Applications PFC stages for Server, Telecom Rectifier, PC Silverbox, Gaming Consoles PWM stages (TTF, LLC) for Server, Telecom Rectifier, PC Silverbox, Gaming Consoles Efficiency Focus toward highes t perfo rmance C3 C6/E6 P6 New products CP C7 Legacy products P6 is optimized for ease-of-use and addresses typical design challenges in high power SMPS, while offering Best-in-Class efficiency on a level close to CoolMOS™ CP: P6 offers good controllability for managing dv/dt (di/dt) and EMI: With an external gate resistor Rg,ext the switching speed can be controlled very well offering the power system designer high flexibility in balancing efficiency vs. EMI P6 is optimized for improved oscillation: parasitic capacitances and inductances in the PCB often lead to unstable designs. P6 comes with a moderate internal Rg providing ease-of-use in the design-in process, yet without reducing switching speed and efficiency (P6 is at the level of CoolMOS™ CP) P6 is suitable for LLC due to its rugged body diode: P6 has a commutation ruggedness sufficient for LLC applications. Combined with its Best-in-Class efficiency in LLC this makes P6 a premier choice for this topology 72 CoolMOS™ P6 P6 is optimized for ease-of-use and addresses typical design challenges Oscillation due to dv/dt Cpar Lpar D Cgd Rg,ext G Cds Rg,in Cgs Oscillation due to di/dt Challenges from fast switching EMI and oscillations from high di/dt → P6 with good controllability for ease-of-use Lsource Challenges in LLC Body diode hard commutation High voltage overshoot High current spike High device stress → P6 with good commutation ruggedness Lpar: Layout parasitic inductance Cpar: Layout parasitic capacitance S P6 for LLC Applications P6 shows the Best-in-Class efficiency over full load range especially at the light load conditions thanks to its low Qg and higher Vth. Main competitor products are at the level of below CoolMOS™ P6 or lower than CoolMOS™ C6. Efficiency comparison of 190mΩ device tested on Infineon 600W LLC board 0.1 0.0 Efficiency difference [%] -0.1 -0.2 -0.3 -0.4 -0.5 -0.6 -0.7 0 5 10 15 20 25 30 35 40 45 50 Load current [A] P6 C6 Comp. A Comp. B P6 for PFC Stages The efficiency of CoolMOS™ P6 is at the level of CoolMOS™ CP and well ahead of competitors while offering much better ease-of-use. This graph shows the PFC efficiency difference at highline for 41mΩ device tested on 2500W board. Efficiency comparison of 41mΩ device @ 65kHz, highline 0.1 0 Efficiency difference [%] CoolMOS™ P6 sets benchmark in LLC efficiency Low Qg improves the light load efficiency Higher Vth improves efficiency due to lower turn-off losses -0.1 P6 reaches similar performance as CP -0.2 P6 efficiency one step ahead of competitors -0.3 200 400 600 800 1000 1200 1400 1600 1800 2000 2200 2400 2600 Pout [W] P6 C6 Comp. A Comp. B Comp. C 73 HV – CoolMOS™ VDS Challenges in PFC VGS out of spec. High switching loss High device stress → P6 optimized for improved oscillation CoolMOS™ C7 New CoolMOS™ C7 Series Highest Efficient MOSFET in the Market With the new CoolMOS™ C7 series Infineon brings a new level of performance in hard switching applications such as Power Factor Correction (PFC). It is the the successor to the CP series and provides efficiency benefits across the whole load range through balancing a number of key parameters. The Best-in-Class RDS(on) leads to increased full load efficiency and enables power density benefits by using smaller packages for the same RDS(on). Eoss reduction brings efficiency benefits at light load and the low Qg correlates to faster switching and lower Eon and Eoff which gives efficiency benefits across the whole load range. The very low Eoss and Qg are the two key parameters in enabling no efficiency loss when moving up in switching frequency. This also enables power density benefits by reducing the size of the circuits magnetic components. Key Features Revolutionary Best-in-Class RDS(on) /package Reduced energy stored in output capacitance Eoss Low gate charge Qg Key Benefits Lowest conduction loss/package Power density by use of smaller packages Low switching losses Enabler to power density by not losing efficiency at higher switching fequencies Improved light load efficiency Power Density – Increased Switching Frequency C7 is an enabler technology that gives customers the stepping stone to new higher switching frequency technologies like GaN but with the proven reliability of Superjunction technology. Competitor A Competitor B CoolMOS™ C7 RDS(on) [mΩ] Paramter 45 36 45 Qg typ [nC] 143 218 93 Eoss [µJ] 13 27,5 11,7 Same losses at higher frequency leads to size reduction of magnetic components for improved power density 65kHz 120kHz Power Density with C7 The higher up the switching frequency of an application goes, the more important parameters such as Eoss and Qg become due to losses of efficiency. The very low values of these parameters in CoolMOS™ C7 minimize losses in a power factor correction (PFC) circuit – at 120kHz the same efficiency can be reached as with the predecessor series at 65kHz. This brings a benefit in power density because the sizes of magnetic components can be reduced. 74 CoolMOS™ C7 Best-in-Class Efficiency in the Industry HV – CoolMOS™ C7 offers the highest efficiency of competitor devices at the same RDS(on) , especially at light load the difference is remarkable. The graph shows the high efficiency when switching at 100kHz in PFC, whereas older technologies such as CP and competitor technologies reduce in efficiency, C7 remains high. Our customers make use of this in 2 ways: Increasing power density – higher switching frequencies are enabled by C7 that enable even smaller magnetic components in circuit and thus allow for much improved form factors Reduced power losses – some customers use C7 for their highest efficiency designs and in order to reduce energy consumption World leading RDS(on) *A Leading to Power Density Benefits 650V C7 vs Competition in TO-247 650V C7 vs Competition in D2PAK/TO-220 100 40 90 36 35 Max. RDS(on) mΩ [@VGS=10V] Max. RDS(on) mΩ [@VGS=10V] 90 80 63 70 60 45 50 40 30 20 29 30 25 20 19 15 10 5 10 0 0 CoolMOS™ C7 Competitor A Competitor B CoolMOS™ C7 Competitor A Competitor B Previous 45mΩ CP in TO-247 (IPW60R045CP) World leading RDS(on) package Now 45mΩ C7 in TO-220 (IPP65R045C7) –– TO-247 package with a 34% lower RDS(on) than the nearest competitor –– TO-220/D²PAK with 29% lower RDS(on) than the nearest competitor As well as improving efficiency, the new RDS(on) values mean a benefit in power density with the ability to now use smaller packages than ever before Difference [%] Efficiency difference @Low line 90Vac Rg (on/off)=10Ω , fsw=100kHz 0,9 0,8 0,7 0,6 0,5 0,4 0,3 0,2 0,1 0 -0,1 -0,2 -0,3 -0,4 -0,5 -0,6 -0,7 -0,8 -0,9 -1 Measured CCM PFC Efficiency (Plug & Play) C7 advantage enables the customer to: Improve efficiency with smaller footprint and enable higher switching frequency 45mΩ 45mΩ 1.6% 36mΩ 36mΩ 0 200 400 600 800 1000 1200 Pout [W] IPW60R045CP TO-247 Competitor 1 TO-247 IPP65R045C7 TO-220 Competitor 2 TO-220 75 CoolMOS™ TO-247 4pin New CoolMOS™ TO-247 4pin Improved Full Load Efficiency via Package Innovation Infineon has introduced the TO-247 4pin package – a package innovation leading to higher efficiency at very reasonable cost. The core idea of this package is to add a 4th pin that acts as a Kelvin Source reducing parasitic inductance, in order to improve efficiency. Motivation and Concept: Source-Sense Concept The idea of the 4th pin, so-called "source sense", is to separate the drive circuit loop from the high current load: The issue with traditional high power through hole packages is that the voltage drop across the source pin (caused by the source inductance) counteracts the gate drive voltage and slows down the switching event. Efficiency loss is the consequence Solution with Infineon’s new TO-247 4pin: –– An additional source pin is added to separate the Source current (pin S) from the Source Sense signal (pin SS) that is used for driving the circuit. Doing so separates the parasitic voltage drop on the source inductance from the gate loop as can be seen in the figure. –– The Source Sense or Kelvin Source connection will have its own parasitic inductance. But this does not play a big negative role, because of the relatively low currents flowing in this circuit. D G + VRG – + VCGS + VDRV – Schematic Symbol – + IDRV VLSS – SS ID + VLS – D G S SS S D S SS G Realization in a Package How this can look like in reality can be seen in the package schematic diagram of the TO-247 4pin package: The lead frame is direct connected to the very left pin, having high clearance and creepage distance to the source pin with its massive bond wires. The following pins for the gate driving do not having high voltage potential, so the distance can be held much smaller. 76 HV – CoolMOS™ CoolMOS™ TO-247 4pin Impact on the Application Performance: CCM PFC Efficiency @100kHz; 90Vac ; 10Ω; IDH16G65C5 96.0 Efficiency [%] 95.5 95.0 94.5 94.0 0.4% 93.5 93.0 200 400 600 800 1000 1200 PFC efficiency comparison between 3pin and 4pin configuration for 90Vac (PFC CCM, Rg=10Ω, IDH16G65C5 @100kHz; 5mm pin length). By connecting the same device (using the 4pin as a standard 3pin and then connecting in the Kelvin Source for a real like-for-like comparison), a benefit of 0.4% efficiency equaling 5W power saving can be seen Pout [W] IPZ65R045C7 (3pin) IPZ65R045C7 (4pin) Impact to the Application Performance: CCM PFC Efficiency @100kHz; 90Vac 96.5 The improved switching performance now offers new opportunities. For example, using a higher ohmic device in 4pin in order to improve efficiency and cost at the same time (in this case, using a 45mΩ device in standard 3pin TO-247 and a 65mΩ device in the TO-247 4pin). Furthermore, the light load efficiency is dramatically improved. 96.0 Efficiency [%] 95.5 95.0 94.5 94.0 93.5 93.0 92.5 92.0 200 400 600 IPW60R045CP, IDH16S60C Pout [W] 800 1000 1200 IPZ65R065C7, IDH16G65C5 77 CoolMOS™ CE New CoolMOS™ CE Superjunction High Voltage MOSFETs Optimized for Consumer Electronics What is CoolMOS™ CE? CoolMOS™ CE is a technology platform of Infineon's market leading high voltage power MOSFET designed according to the Superjunction principle (SJ) and conceived to fulfill consumer requirements CoolMOS™ CE portfolio offers 500V, 600V, 650V and 800V devices targeting low Power Chargers, Adapters, LCD, LED TV and LED Lighting and Power Tools applications This new series of CoolMOS™ is cost optimized to meet typical requirements in consumer application CoolMOS™ CE is suitable for hard and soft switching applications and as modem SJ, it delivers low conduction and switching losses improving efficiency and ultimately reduces power consumption CoolMOS™ CE's ease-of-use enables customers to reduce the design-in cycle and compete in dynamic markets Features Technical Benefits Customer Benefits Narrow margins between typical Low conduction losses Low switching losses Suitable for hard and soft switching Easy controllable of switching behavior Improved efficiency and consequent reduction of and max RDS(on) Reduced energy stored in output capacitance (Eoss) Good body diode ruggedness and reduced reverse recovery charge (Qrr) power consumption Less design-in effort Ease-of-use Optimized integrated gate resistor (Rg) Topology Voltage Class Technology Benefit DCM/CCM PFC, HB LLC 500V CE Easy control of switching behavior due to higher Rg,int DCM PFC, HB LLC 500V/600V CE Better transition losses vs. standard MOSFET Easy control of switching behavior even in not optimized layout Better switching losses in comparison with its predecessor Rugged body diode which prevents device failure during hard commutation Flyback 600V/650V/800V CE Best price competitive CoolMOS™ family Lower switching losses vs. standard MOSFET Controlled dv/dt & di/dt for better EMI 78 CoolMOS™ Automotive 600V CoolMOS™ CPA and 650V CoolMOS™ CFDA Automotive Technology in Pole Position HV – CoolMOS™ After launching the first series of high voltage Automotive MOSFET, the 600V CoolMOS™ CPA series, Infineon has launched its second generation of market leading Automotive qualified high voltage MOSFET, the 650V CoolMOS™ CFDA series. The 600V CoolMOS™ CPA portfolio and the broad 650V CoolMOS™ CFDA portfolio provide all benefits of a fast switching Superjunction MOSFET while fulfilling the enhanced reliability requirements for Automotive applications realized with special screening measures in front end and back end as well as qualification compliant to AEC Q100. The 650V CoolMOS™ CFDA series additionally caters to special application needs with its integrated Fast Body Diode. This Fast Body Diode is the key for addressing resonant switching topologies resulting in lower switching losses due to the low gate charge. The softer commutation behavior and consequent reduced EMI appearance gives the 650V CoolMOS™ CFDA series a clear advantage in comparison to competitor parts. Furthermore, limited voltage overshoot during hard commutation of the body diode enables easier implementation of layout and design. Therefore, the combination of both the 600V CoolMOS™ CPA and the new 650V CoolMOS™ CFDA technologies are the best choice for switching topologies in Automotive applications. Common Key Features CoolMOS™ "A" First 600V/650V Automotive qualified high voltage technologies for automotive market Compliant to AEC Q101 standard Key Features 600V CoolMOS™ CPA Lowest RDS(on) per package Lowest gate charge value Qg Applications 600V CoolMOS™ CPA Hard switching topologies PFC boost stages in On-Board Charger Active clamp or 2 transistor forward in DC/DC Converter Key Features 650V CoolMOS™ CFDA Limited voltage overshoot during hard commutation – self-limiting di/dt and dv/dt Low Qrr at repetitive commutation on body diode and low Qoss Applications 650V CoolMOS™ CFDA Resonant switching topologies LLC or full bridge ZVS in DC/DC Converter HID Lamp 79 CoolMOS™ Product Table 500V CoolMOS™ CE ID [A] RDS(on) [mΩ] TO-220 TO-220 FullPAK TO-247 TO-252 (DPAK) TO-251 (IPAK) 18.5 190 IPP50R190CE IPA50R190CE IPW50R190CE 7.5-13.0 280 IPP50R280CE IPA50R280CE IPW50R280CE 6.3-9.9 380 IPP50R380CE IPA50R380CE IPD50R380CE 5.4-7.6 500 IPP50R500CE IPA50R500CE IPD50R500CE 4.6-6.1 650 IPA50R650CE IPD50R650CE 4.1-5.0 800 IPA50R800CE IPD50R800CE 3.7-4.3 950 IPA50R950CE IPD50R950CE IPU50R950CE 3.1 1400 IPD50R1K4CE IPU50R1K4CE 2.4 2000 IPD50R2K0CE IPU50R2K0CE 1.5 3000 IPD50R3K0CE IPU50R3K0CE TO-251 (IPAK SL) IPD50R280CE 600V CoolMOS™ CE 80 ID [A] RDS(on) [mΩ] TO-220 TO-220 FullPAK TO-247 TO-252 (DPAK) TO-251 (IPAK) 10.3 400 IPA60R400CE IPD60R400CE 9.1 460 IPA60R460CE IPD60R460CE 7.0 650 IPA60R650CE IPD60R650CE 5.6 800 IPA60R800CE IPD60R800CE 4.3 1000 IPD60R1K0CE IPU60R1K0CE 3.1 1500 IPD60R1K5CE IPU60R1K5CE 2.3 2100 IPD60R2K1CE IPU60R2K1CE TO-251 (IPAK SL) HV – CoolMOS™ CoolMOS™ Product Table 650V CoolMOS™ CE ID [A] RDS(on) [mΩ] TO-220 TO-220 FullPAK TO-247 TO-252 (DPAK) TO-251 (IPAK) TO-251 (IPAK SL) 400 IPS65R400CE1) 650 IPS65R650CE1) 4.3 1000 IPS65R1K0CE 3.1 1500 IPS65R1K5CE 800V CoolMOS™ CE ID [A] RDS(on) [mΩ] TO-220 TO-220 FullPAK TO-247 TO-252 (DPAK) TO-251 (IPAK) 6.8 310 IPA80R310CE 5.0 460 IPA80R460CE 4.5 650 IPA80R650CE 3.6-5.7 1000 IPA80R1K0CE IPD80R1K0CE IPU80R1K0CE 2.8-3.9 1400 IPA80R1K4CE IPD80R1K4CE IPU80R1K4CE 1.9 2800 IPD80R2K8CE IPU80R2K8CE TO-251 (IPAK SL) 1) Coming Q3 2015 81 CoolMOS™ Product Table 600V CoolMOS™ C6 ID [A] RDS(on) [mΩ] TO-220 TO-262 (I2PAK) TO-263 (D2PAK) TO-220 FullPAK TO-247 TO-252 (DPAK) 77.5 41 IPW60R041C6 53.0 70 IPW60R070C6 57.7 74 IPP60R074C6 38.0 99 IPP60R099C6 IPB60R099C6 IPA60R099C6 IPW60R099C6 30.0 125 IPP60R125C6 IPB60R125C6 IPA60R125C6 IPW60R125C6 23.8 160 IPP60R160C6 IPB60R160C6 IPA60R160C6 IPW60R160C6 20.2 190 IPP60R190C6 IPI60R190C6 IPB60R190C6 IPA60R190C6 IPW60R190C6 13.8 280 IPP60R280C6 IPI60R280C6 IPB60R280C6 IPA60R280C6 IPW60R280C6 10.6 380 IPP60R380C6 IPI60R380C6 IPB60R380C6 IPA60R380C6 IPD60R380C6 8.1 520 IPP60R520C6 IPA60R520C6 IPD60R520C6 7.3 600 IPP60R600C6 IPB60R600C6 IPA60R600C6 IPD60R600C6 4.4 950 IPP60R950C6 IPB60R950C6 IPA60R950C6 3.2 1400 IPP60R1K4C6 IPD60R950C6 IPD60R1K4C6 IPL60R1K5C6S 1500 2.4 IPD60R2K0C6 2000 IPL60R2K1C6S 2100 1.7 ThinPAK 5x6 3300 IPD60R3K3C6 650V CoolMOS™ C6 ID [A] RDS(on) [mΩ] TO-220 TO-262 (I2PAK) TO-263 (D2PAK) TO-220 FullPAK TO-247 TO-252 (DPAK) 83,2 37 IPW65R037C6 53,5 70 IPW65R070C6 57,7 74 IPP65R074C6 38,0 99 IPP65R099C6 IPI65R099C6 IPB65R099C6 IPA65R099C6 IPW65R099C6 20,2 190 IPP65R190C6 IPI65R190C6 IPB65R190C6 IPA65R190C6 IPW65R190C6 16,1 250 13,8 280 IPP65R280C6 IPI65R280C6 IPB65R280C6 IPA65R280C6 IPW65R280C6 10,6 380 IPP65R380C6 IPI65R380C6 IPB65R380C6 IPA65R380C6 IPD65R380C6 7,3 600 IPP65R600C6 IPI65R600C6 IPB65R600C6 IPA65R600C6 IPD65R600C6 IPD65R250C6 IPL65R650C6S 650 4,5 3,2 82 ThinPAK 5x6 950 IPD65R950C6 1000 IPD65R1K0C6 IPL65R1K0C6S 1400 IPD65R1K4C6 IPL65R1K5C6S CoolMOS™ Product Table 600V CoolMOS™ E6 RDS(on) [mΩ] 20.2 190 IPP60R190E6 IPA60R190E6 IPW60R190E6 13.8 280 IPP60R280E6 IPA60R280E6 IPW60R280E6 10.6 380 IPP60R380E6 IPA60R380E6 IPD60R380E6 9.2 450 IPP60R450E6 IPA60R450E6 IPD60R450E6 8.1 520 IPP60R520E6 IPA60R520E6 IPD60R520E6 7.3 600 IPP60R600E6 IPA60R600E6 IPD60R600E6 5.7 750 IPP60R750E6 IPA60R750E6 IPD60R750E6 TO-220 TO-262 (I2PAK) TO-263 (D2PAK) TO-220 FullPAK TO-247 TO-252 (DPAK) ThinPAK 8x8 HV – CoolMOS™ ID [A] 650V CoolMOS™ E6 ID [A] RDS(on) [mΩ] 20.2 190 16.1 250 13.8 280 13.1 310 10.6 380 TO-220 TO-262 (I2PAK) TO-263 (D2PAK) TO-220 FullPAK IPP65R190E6 IPA65R190E6 TO-247 TO-252 (DPAK) IPW65R190E6 IPL65R190E6 IPD65R250E6 IPP65R280E6 IPI65R280E6 IPB65R280E6 IPA65R280E6 IPW65R280E6 IPL65R310E6 IPP65R380E6 IPA65R380E6 IPD65R380E6 IPL65R420E6 420 7.3 600 6.7 660 ThinPAK 8x8 IPP65R600E6 IPA65R600E6 IPD65R600E6 IPL65R660E6 800V CoolMOS™ C3 ID [A] RDS(on) [mΩ] TO-220 TO-262 (I2PAK) TO-263 (D2PAK) TO-220 FullPAK TO-247 TO-252 (DPAK) SPW55N80C3 54.9 85 17.0 290 SPP17N80C3 11.0 450 SPP11N80C3 8.0 650 SPP08N80C3 6.0 900 SPP06N80C3 SPA06N80C3 SPD06N80C3 4.0 1300 SPP04N80C3 SPA04N80C3 SPD04N80C3 2.0 2700 SPP02N80C3 SPA02N80C3 SPD02N80C3 SPB17N80C3 SPI08N80C3 SPA17N80C3 SPW17N80C3 SPA11N80C3 SPW11N80C3 SPA08N80C3 900V CoolMOS™ C3 ID [A] RDS(on) [mΩ] 36.0 120 TO-220 TO-262 (I2PAK) TO-263 (D2PAK) TO-220 FullPAK TO-247 TO-252 (DPAK) IPW90R120C3 10.0-15.0 340 IPP90R340C3 IPI90R340C3 IPB90R340C3 IPA90R340C3 IPW90R340C3 11.0 500 IPP90R500C3 IPI90R500C3 IPA90R500C3 6.9 800 IPP90R800C3 IPI90R800C3 IPA90R800C3 IPW90R500C3 IPW90R800C3 5.7 1000 IPP90R1K0C3 IPI90R1K0C3 IPA90R1K0C3 IPW90R1K0C3 3.1-5.1 1200 IPP90R1K2C3 IPI90R1K2C3 IPA90R1K2C3 IPW90R1K2C3 IPD90R1K2C3 83 CoolMOS™ Product Table 600V CoolMOS™ P6 ID [A] 53.5 37.9 30.0 10.4-23.8 9.5-20.2 19.2 8.6-16.8 15.9 7.7-13.8 7.0-12.0 6.5-10.6 4.9-7.3 6.7 RDS(on) [mΩ] 41 70 99 125 160 180 190 210 230 255 280 330 380 600 650 TO-220 TO-263 (D2PAK) TO-220 FullPAK TO-247 IPB60R160P61) IPA60R099P6 IPA60R125P6 IPA60R160P6 IPW60R041P6 IPW60R070P6 IPW60R099P6 IPW60R125P6 IPW60R160P6 IPP60R190P6 IPB60R190P61) IPA60R190P6 IPW60R190P6 IPP60R230P6 IPB60R230P61) IPA60R230P6 IPW60R230P6 IPP60R280P6 IPP60R330P6 IPP60R380P6 IPP60R600P6 IPB60R280P61) IPB60R330P61) IPB60R380P61) IPB60R600P61) IPA60R280P6 IPA60R330P6 IPA60R380P6 IPA60R600P6 IPW60R280P6 IPW60R330P6 IPP60R099P6 IPP60R125P6 IPP60R160P6 TO-247 4pin TO-252 (DPAK) ThinPAK 5x6 ThinPAK 8x8 IPZ60R041P61) IPZ60R070P61) IPZ60R099P61) IPZ60R125P61) IPL60R180P6 IPL60R210P6 IPL60R255P6 IPD60R380P6 IPD60R600P6 IPL60R650P6S 650V CoolMOS™ C7 ID [A] RDS(on) [mΩ] 75.0 18.0-46.0 15.0-33.0 28.0 12.0-24.0 19 45 65 70 95 99 125 130 190 195 225 230 10.0-18.0 15.0 8.0-13.0 12.0 7.0-11.0 10.0 TO-220 TO-263 (D2PAK) TO-220 FullPAK TO-247 TO-247 4pin IPP65R065C7 IPB65R045C7 IPB65R065C7 IPA65R045C7 IPA65R065C7 IPW65R019C7 IPW65R045C7 IPW65R065C7 IPZ65R019C7 IPZ65R045C7 IPZ65R065C7 IPP65R095C7 IPB65R095C7 IPA65R095C7 IPW65R095C7 IPZ65R095C7 IPP65R125C7 IPB65R125C7 IPA65R125C7 IPW65R125C7 IPP65R190C7 IPB65R190C7 IPA65R190C7 IPW65R190C7 IPP65R225C7 IPB65R225C7 IPA65R225C7 TO-252 (DPAK) ThinPAK 8x8 IPL65R070C7 IPL65R099C7 IPL65R130C7 IPD65R190C7 IPL65R195C7 IPD65R225C7 IPL65R230C7 650V CoolMOS™ CFD2 ID [A] RDS(on) [mΩ] TO-220 TO-263 (D2PAK) TO-220 FullPAK TO-247 TO-252 (DPAK) 68.5 41 IPW65R041CFD 43.3 80 IPW65R080CFD 31.2 110 IPP65R110CFD IPI65R110CFD IPB65R110CFD IPA65R110CFD IPW65R110CFD 22.4 150 IPP65R150CFD IPI65R150CFD IPB65R150CFD IPA65R150CFD IPW65R150CFD 21.3 165 17.5 190 IPP65R190CFD IPI65R190CFD IPB65R190CFD IPA65R190CFD IPW65R190CFD IPP65R310CFD IPI65R310CFD IPB65R310CFD IPA65R310CFD IPW65R310CFD IPP65R420CFD IPI65R420CFD IPB65R420CFD IPA65R420CFD IPW65R420CFD IPD65R420CFD IPP65R660CFD IPI65R660CFD IPB65R660CFD IPA65R660CFD IPW65R660CFD IPD65R660CFD ThinPAK 8x8 IPL65R165CFD 16.1 210 11.4 310 10.9 340 8.7 420 8.3 460 6.0 660 5.8 725 3.9 950 IPD65R950CFD 3.2 1400 IPD65R1K4CFD IPL65R210CFD IPL65R340CFD IPL65R460CFD 1) Coming Q3 2015 84 TO-262 (I2PAK) IPL65R725CFD CoolMOS™ Product Table CoolMOS™ Automotive Product Type RDS(on) @ TJ = 25°C VGS = 10V [mΩ] ID (max) @ TJ = 25°C [A] IDpuls (max) [A] VGS(th) (min-max) [V] QG (typ) [nC] RthJC (max) [K/W] Package 105 31 93 -20 … 20 60 0,5 TO-263 IPB60R199CPA 199 16 51 -20 … 20 32 0,9 TO-263 IPB60R299CPA 299 11 34 -20 … 20 22 1,3 TO-263 IPP60R099CPA 105 31 93 -20 … 20 60 0,5 TO-220 IPW60R045CPA 45 60 230 -20 … 20 150 0,29 TO-247 IPW60R075CPA 75 39 130 -20 … 20 87 0,4 TO-247 IPW60R099CPA 105 31 93 -20 … 20 60 0,5 TO-247 IPI60R099CPA 105 31 93 -20 … 20 60 0,5 TO-262 IPB60R099CPA HV – CoolMOS™ 600V CoolMOS™ CPA Product Portfolio 650V CoolMOS™ CFDA Product Portfolio Product Type RDS(on) @ TJ = 25°C VGS = 10V [mΩ] ID (max) @ TJ = 25°C [A] IDpuls (max) [A] VGS(th) (min-max) [V] QG (typ) [nC] RthJC (max) [K/W] Package IPD65R420CFDA 420 8,7 27 3.5...4.5 32 1,5 TO-252 IPD65R660CFDA 660 6 17 3.5...4.5 20 2 TO-252 IPB65R110CFDA 110 31,2 99,6 3.5...4.5 11 0,45 TO-263 IPB65R150CFDA 150 22,4 72 3.5...4.5 86 0,64 TO-263 IPB65R190CFDA 190 17,5 57,2 3.5...4.5 68 0,83 TO-263 IPB65R310CFDA 310 11,4 34,4 3.5...4.5 41 1,2 TO-263 IPB65R660CFDA 660 6 17 3.5...4.5 20 2 TO-263 IPP65R110CFDA 110 31,2 99,6 3.5...4.5 11 0,45 TO-220 IPP65R150CFDA 150 22,4 72 3.5...4.5 86 0,64 TO-220 IPP65R190CFDA 190 17,5 57,2 3.5...4.5 68 0,83 TO-220 IPP65R310CFDA 310 11,4 34,4 3.5...4.5 41 1,2 TO-220 IPP65R660CFDA 660 6 17 3.5...4.5 20 2 TO-220 IPW65R048CFDA 48 63,3 228 3.5...4.5 27 0,25 TO-247 IPW65R080CFDA 80 43,3 127 3.5...4.5 16 0,32 TO-247 IPW65R110CFDA 110 31,2 99,6 3.5...4.5 11 0,45 TO-247 IPW65R150CFDA 150 22,4 72 3.5...4.5 86 0,64 TO-247 IPW65R190CFDA 190 17,5 57,2 3.5...4.5 68 0,83 TO-247 85 CoolMOS™ Nomenclature Naming System Power MOSFETs (Naming System Until 2005) S P P 20 N 60 Company S = Formerly Siemens C 3 Specifications C3 = CoolMOSTM C3 S5 = CoolMOSTM S5 Device P = Power MOSFET Breakdown Voltage Divided by 10 (60 x 10 = 600V) Package Type A = TO-220 FullPAK B = TO-263 (D2PAK) D = TO-252 (DPAK) I = TO-262 (I2PAK) N = SOT-223 P = TO-220 U = TO-251 (IPAK) W = TO-247 Z = TO-247 4pin Technology N = N-Channel Transistors Continuous Drain Current (@ TC = 25°C) [A] Power MOSFETs (Naming System From 2005 Onwards) I P P 60 099 R C P Company I = Infineon Series Name in this case CoolMOSTM CP for PFC and PWM applications Device P = Power MOSFET RDS(on) [mΩ] Package Type A = TO-220 FullPAK B = TO-263 (D2PAK) D = TO-252 (DPAK) I = TO-262 (I2PAK) L = ThinPAK 8x8 N = SO-T223 P = TO-220 U = TO-251 (IPAK) W = TO-247 Z = TO-247 4pin R = RDS(on) Breakdown Voltage Divided by 10 (60 x 10 = 600V) Automotive MOSFETs I 86 P P 60 R 099 C P A Infineon Automotive Power MOSFET Series Name CoolMOS™ CP and CoolMOS™ CFD Package Type B = PG-TO263 (D2PAK) I = PG-TO262 (I2PAK) P = PG-TO220 W = PG-TO247 RDS(on) [m] R = RDS(on) Breakdown Voltage Divided by 10 (60 x 10 = 600V) CoolMOS™ Support Expert Support for CoolMOS™ Easy Access and High Quality Application Notes, Datasheets & More www.infineon.com/coolmos-500V-650V www.infineon.com/coolmos-800V-900V Latest Videos www.infineon.com/mediacenter High Voltage Evaluation Boards www.infineon.com/300w-pfc-evaluationboard www.infineon.com/2kW-zvs-evaluationboard www.infineon.com/600w-llc-evaluationboard-a www.infineon.com/600w-llc-evaluationboard-d Datasheets 87 Silicon Carbide Diodes Silicon Carbide Diodes Improve Efficiency and Solution Costs Silicon Carbide (SiC) devices belong to the so-called wide band gap semiconductor group, which offers a number of attractive characteristics for high voltage power semiconductors when compared to commonly used Silicon (Si). In particular, the much higher breakdown field strength and thermal conductivity of SiC allow creating devices which outperform by far the corresponding Si ones, and enable reaching otherwise unattainable efficiency levels. Silicon Carbide Schottky Diodes The differences in material properties between SiC and Silicon limit the fabrication of practical Silicon unipolar diodes (Schottky diodes) to a range up to 100V – 150V, with relatively high on-state resistance and leakage current. On the other hand, SiC Schottky barrier diodes (SBD) can reach a much higher breakdown voltage. Infineon offers products up to 1200V as discrete and up to 1700V in modules. Features Benefits System efficiency improvement compared to Si diodes Reduced cooling requirements Enabling higher frequency/ increased power density Higher system reliability due to lower operating temperature Reduced EMI Benchmark switching behavior No reverse recovery charge Temperature independent I [A] switching behavior High operating temperature (Tj, max 175°C) 10 8 6 4 2 0 -2 -4 -6 -8 -10 0.07 T=125°C, VDC=400V, IF=6A, di/dt=200 A/µs Applications Server Telecom Solar UPS PC Silverbox Motor Drives Lighting Reverse Recovery Charge of SiC versus Silicon Devices The majority carrier characteristics of the device imply no reverse recovery charge and the only contribution to the switching losses comes from the tiny displacement charge of capacitive nature. In the same voltage range, Silicon devices show a bipolar component resulting in much higher switching losses. Here the comparison between various 600V devices. 0.25 0.16 0.19 0.22 Time [µs] SiC Schottky diode: SDB06S60 Ultrafast Si pin diode Si pin double diode (2*300V) 0.1 0.13 Improved System Efficiency (PFC in CCM Mode Operation, Full Load, Low Line) The fast switching characteristics of the SiC diodes provide clear efficiency improvements at system level. The performance gap between SiC and high-end Silicon devices increases with the operating frequency. 95.0 Efficiency [%] 94.5 94.0 93.5 93.0 92.5 92.0 91.5 91.0 60 120 180 Switchting Frequency [kHz] IFX SiC 6A 88 Comp. 1 6A 240 Comp. 2 6A Silicon Carbide Diodes Infineon is the world’s first SiC discrete power supplier. Long market presence and experience enable Infineon to deliver highly reliable, industry-leading SiC performance. With over 10 years pioneering experience in developing and manufacturing SiC diodes, Infineon’s latest thinQ!™ SiC Schottky Diodes Generation 5 family sets benchmark in quality, efficiency and reliability. 650V SiC thinQ!™ Generation 5 Schottky Diodes: Best Price/Performance This product family has been optimized from all key aspects including junction structure, substrate, and die attach. It represents a well-balanced product family which offers state of the art performance and high surge current capability at competitive cost level. p+ p+ p+ p+ Ti p+ epi layer field stop layer SiC substrate 110µm backside & packaging diffusion soldering Substrate: Thin Wafer Technology On the substrate level, Infineon introduced thin wafer technology, at the later stage of our SiC diode production thin wafer process is used to reduce the wafer thickness by about 2/3, this significantly reduces the substrate resistance contribution thus improve both VF and thermal performance. Die Attach: Diffusion Soldering On the backside and package level diffusion soldering is introduced which significantly improves the thermal path between lead frame and the diode, enhancing the thermal performance. With the same chip size and power dissipation, the junction temperature is reduced by 30°C. ent 35 ge c urr 30 25 sur IF (A) Al 40 20 15 10 5 0 0.00 2.00 4.00 8.00 10.00 12.00 14.00 VF (V) Combined characteristic Schottky diode forward characteristic Bipolar pn diode forward characteristic 60 50 IF [A/mm2] Al wire bond Junction: Merged PN Structure On the junction level, it has an optimized merged PN structure. Compared to competitors Infineon SiC diode has additional P doped area, together with the N doped EPI layer, it forms a PN junction diode. Thus it is a combination of Schottky diode and PN junction diode. Under normal conditions, it works like a standard Schottky diode. Under abnormal conditions, such as lighting, AC line drop-out, it works like a PN junction diode. At high current level, the PN junction diode has significantly lower VF than Schottky diode, this leads to less power dissipation, thus significantly improving the surge current capability. Silicon Carbide Innovation: Optimized Junction, Substrate and Die Attach Infineon Generation 5 SiC Schottky diode is optimized with regard to all key aspects relevant for high power and high efficiency SMPS applications. 40 30 20 10 0 0 2 Generation 5 4 VF [V] 6 8 Generation 2, 3 Diffusion Soldering RthJC=2.0 K/W RthJC=1.5 K/W 89 SiC Generation 5 Optimum Balance of Efficiency and Surge Current Capability 8A SiC Diode Comparison from Different Suppliers Figure of Merit (Qc x VF / nC-V) [Efficiency] 60 Performance frontier 50 40 30 20 Balance and Trend 10 0 0 20 40 60 80 100 120 Surge current capability Infineon Comp. 1 Comp. 2 Comp. 3 Comp. 4 Generation 5 SiC Schottky diode offers the optimum efficiency and ruggedness balance. Lower VF means lower conduction loss and lower Qc means lower switching loss. Qc x VF is the Figure of Merit for efficiency and comparison indicates that Generation 5 matches the best competitors on the market. In addition, SiC Generation 5 offers a surge current robustness far better than that offered by the most efficient products. Thus under abnormal conditions this surge current capability offers excellent device robustness. All over, SiC Generation 5 offers excellent efficiency and surge current capability at the same time. No other SiC diode product on the market offers such good balance between efficiency and surge current capability. Some vendors offer better efficiency but weak surge current; while others offer better surge current but are less attractive in efficiency. Efficiency Comparison CCM mode PFC, high line, Pmax = 1800W, fSW = 65kHz; MOSFET: IPW65R095C7, SiC Diode: TO-220 8A 98.6 0.05 Efficiency Difference [%] Efficiency [%] 98.4 98.2 98.0 97.8 97.6 97.4 -0.05 0.15 0 500 1000 1500 2000 0 500 Pout [W] Generation 5 1000 1500 2000 Pout [W] Comp. 3 Comp. 4 Generation 5 Comp. 3 Comp. 4 In terms of efficiency, 8A device has been tested in CCM PFC. The maximum output power is 1.8kW and switching frequency is 65kHz. The left figure shows the absolute efficiency as a function load power, while right figure shows efficiency difference compared to our Generation 5 SiC diode. It is obvious Infineon Generation 5 delivers better efficiency over full load range. 90 SiC Generation 5 System Solution for PFC Generation 2 C7 P6 Generation 3 Generation 5 Best-in-Class Silicon Carbide Price Efficiency The thinQ!™ SiC Schottky diode Generation 5 is in perfect combination with Infineon’s CoolMOS™ for best performance and efficiency in PFC stages. The target applications in this case are Telecom, Server, etc. We recommend thinQ!™ SiC Schottky diode Generation 5 for new designs. The selection of CoolMOS™ and thinQ!™ depends on target efficiency and cost. Price/ Performance Si Performance (efficiency, density) Design-in effort Easy Hard Infineon System Solution in PFC CCM PFC Power [W] CoolMOS™ RDS(on) [mΩ] thinQ!™ SiC Diode IF [A] Server Telecom Server and Telecom 500 1 x 190 1 x 190 1 x (4~6) 750 1 x 99/2 x 190 2 x 190 1 x (6~8) 1200 2 x (70~99) 2 x 99 2 x (6~8)/1 x (12~16) 2000 2700 3000 1 x (8~10) 3 x (41~80) 2 x (8~10)/1 x (16~20) 2 x 65/1 x 19 2 x (8~10)/1 x (16~20) RDS(on) depends on target efficiency level, switching frequency and thermal management SiC diode current level depends on switching frequency, current limitation and thermal management New 1200V SiC thinQ!™ Generation 5 Schottky Diodes : High Efficiency/Compact By using hybrid Si IGBT/SiC diode sets, designers of industrial applications will gain flexibility for system optimization compared to Silicon based solution. The keys are reduced cooling requirements, higher output power or higher switching frequency at high efficiency. In the new 1200V thinQ!™ Generation 5 SiC Schottky diodes, the zero reverse recovery charge comes with a reduction of forward voltage and extended surge current capability compared to previous generation. The ultra-low forward voltage, even at high operating temperature, results in 30% static loss gain versus previous generation during full-load condition. Implementing Generation 5 thinQ!™ diodes in combination with Infineon’s 1200V HighSpeed 3 IGBT, designers can achieve outstanding system level performance and reliability. 91 SiC Generation 5 Key Benefits 1200V SiC vs. 1200V Si diodes Key Features 1200V SiC vs. 1200V Si diodes No reverse recovery charge No voltage overshoots due to zero forward recovery Switching behavior independent from forward current, switching speed and temperature Virtually no diode switching losses and thereby lower Si IGBT losses → high system efficiency Reduced EMI Higher system reliability Higher switching frequency for high efficiency Key Features 1200V Gen5 vs. 1200V Gen2 Low forward voltage (VF) Mild positive temperature dependency of VF Extended surge current capability Excellent thermal performance Up to 40A rated diode Key Benefits 1200V G5 vs. 1200V G2 Higher efficiency through up to 30% gain in diode losses Reduced cooling requirements through lower diode losses and lower case temperatures Better system reliability through extended surge current up to 14x nominal current Applications Solar Inverters UPS 3-phase SMPS Motor Drives Surge Current: 10A diodes 16 2.4 14 2.2 12 Lowest VF - Level with Generation 5 2.0 1.8 +60% IFSM/ Inom Forward Voltage @ Inom [V] Forward Voltage: 30A diodes 2.6 +31% +21% 1.4 +29% 14 x Inom Surge current with Generation 5 9 10 8 5 6 1.6 5 4 2 1.2 1.0 14 Generation 2 Generation 5 Comp. 1 Tj = 25°C 0 Comp. 2 Generation 2 Generation 5 Comp. 1 Comp. 2 Tj = 150°C Front-End Booster Stage of a Photovoltaic Inverter: Vin = 500V, Vout = 800V, 20kHz, Tj = 125 °C Diode Losses Diode Losses % 0.50 50 0.43% 0.40 Losses [% from Pout] Losses [W] 40 30 20 10 0 0 20 40 60 80 100 0.20 0.10 0.19% 0.22% 0.20% 1 kW 5kW Nominal Power [%] IDW10S120 92 0.31% 0.27% 0.30 10kW Output Power IDW10G120C5 IDW10S120 IDW10G120C5 SiC CoolSiC™ CoolSiC™ 1200V SiC JFET & Direct Drive JFET Topology Features Extremely low and temperature independent switching losses Excellent high load efficiency compared to IGBTs Monolithically integrated SiC body diode Benefits Reduced cooling effort due to reduced losses Increase of the operating frequency with consequent shrink of passive components and savings at system level Increased power density Dedicated driver for direct JFET control High reliability due to missing gate oxide Structural elements similar to SiC diodes, with > 10 years proved experience in manufacturing Silicon Carbide CoolSiC™ 1200V SiC JFET family, in combination with the proposed Direct Drive JFET Topology, represents Infineon’s leading edge solution to bring actual designs towards new and so far unattainable efficiency borders. The SiC JFET offers Best-in-Class switching loss behavior with respect to 1200V IGBT with comparable conduction losses available. Utmost efficiency at highest power density levels can be reached also thanks to Infineon CoolSiC™ monolithically integrated body diode, showing a switching performance comparable with that of an external SiC Schottky barrier diode. The Infineon SiC JFET, with its ultrafast SiC body diode and dedicated driver, represents the best solution in Solar, UPS and Industrial Drives applications by combining best performance, reliability, safety and ease-of-use. Increase of output power, reduction of specific system cost Applications Solar UPS Industrial Drives C V CC SGND Controller Rg_J JFDrv VCC GND1 MDrv IN VReg EN CLJFG Rg_M C V_Reg LV MOSFET VCC1 +5V to SGND CoolSiC™ JFET Drain cascode C VEE2 VEE2 BSEN -25 V to VCC2 Source cascode 1EDI30J12Cx CoolSiC™ 1200V JFET Portfolio and Recommended Driver/LV MOS for Direct Drive JFET Topology RDS(on) [mΩ] Voltage 1200 1200 Sales name JFET Package Driver Driver Package LV MOS LV MOS Package 70 IJW120R070T1 TO-247 1EDI30J12CL/CP DSO-16-20/19-4 BSC030P03NS3 G SuperSO8 100 IJW120R100T1 TO-247 1EDI30J12CL/CP DSO-16-20/19-4 BSC030P03NS3 G SuperSO8 70 IJC120R070T1 Bare die 1EDI30J12CL/CP DSO-16-20/19-4 IPC099P03N Bare die 100 IJC120R100T1 Bare die 1EDI30J12CL/CP DSO-16-20/19-4 IPC099P03N Bare die 93 SiC Diodes Product Table 650V Generation 5 TO-220 R2L IF [A] TO-247 Dual Die TO-247 DPAK DML D2PAK R2L ThinPAK 8x8 2 IDH02G65C5 IDK02G65C5 3 IDH03G65C5 IDK03G65C5 4 IDH04G65C5 IDK04G65C5 5 IDH05G65C5 IDK05G65C5 6 IDH06G65C5 IDK06G65C5 IDL06G65C5 8 IDH08G65C5 IDK08G65C5 IDL08G65C5 9 IDH09G65C5 IDK09G65C5 10 IDH10G65C5 IDW10G65C5 IDK10G65C5 IDL10G65C5 12 IDH12G65C5 IDW12G65C5 IDK12G65C5 IDL12G65C5 16 IDH16G65C5 IDW16G65C5 20 IDH20G65C5 IDW20G65C5B* IDL02G65C5 IDL04G65C5 IDW20G65C5 24 IDW24G65C5B* 30/32 IDW32G65C5B* IDW30G65C5 40 IDW40G65C5B* IDW40G65C5 600V Generation 3 TO-220 R2L IF [A] TO-247 Dual Die TO-247 DPAK DML 3 IDH03SG60C IDD03SG60C 4 IDH04SG60C IDD04SG60C 5 IDH05SG60C IDD05SG60C 6 IDH06SG60C IDD06SG60C 8 IDH08SG60C IDD08SG60C 9 IDH09SG60C IDD09SG60C 10 IDH10SG60C IDD10SG60C 12 IDH12SG60C IDD12SG60C D2PAK ThinPAK 8x8 D2PAK DML ThinPAK 8x8 600V Generation 2 TO-220 R2L IF [A] 4 IDH04S60C** 5 IDH05S60C** 6 IDH06S60C** 8 IDH08S60C** 10 IDH10S60C** 12 IDH12S60C** 16 IDH16S60C** *to be released in 2015 **not for new designs 94 TO-247 Dual Die TO-247 DPAK DML IDB06S60C** IDB10S60C** Silicon Carbide SiC Diodes Product Table 1200V Generation 5 IF [A] TO-220 R2L TO-247 Dual Die TO-247 DPAK DML 2 IDH02G120C5* IDM02G120C5* 5 IDH05G120C5* IDM05G120C5* 8 IDH08G120C5* 10 IDH10G120C5* IDW10G120C5B 15 IDH15G120C5* IDW15G120C5B D2PAK DML ThinPAK 8x8 D2PAK DML ThinPAK 8x8 IDM08G120C5* 20 IDW20G120C5B 40 IDW40G120C5B 1200V Generation 2 IF [A] TO-220 R2L 2 IDH02SG120 5 IDH05S120 8 IDH08S120 TO-247 Dual Die TO-247 10 IDH10S120 IDW10S120** 15 IDH15S120 IDW15S120** 20 DPAK DML IDW20S120** 95 SiC Diodes Nomenclature Naming System thinQ!™ Silicon Carbide Schottky Diodes Generation 2 and 3 I D H X S G X C Company I = Infineon Specifications C = Surge current stable Device D = Diode Breakdown Voltage 60 = 600V 120 = 1200V Package Type D = DPAK H = TO-220 real 2 pin B = D2PAK D = DPAK = TO-220 V = TO-220FP W = TO-247 G = Low thermal resistance (diffusion soldering) Technology S = SiC Diode Continuous Forward Current [A] thinQ!™ Silicon Carbide Schottky Diodes Generation 5 I D H X G X C 5 B Company I = Infineon B = Dual die Device D = Diode Series Name 5 = Generation 5 Package Type H = TO-220 real 2 pin W = TO-247 K = D2PAK R2L L = ThinPAK 8x8 M = DPAK DML Specifications C = Surge current stable Continuous Forward Current [A] G = Low thermal resistance Breakdown Voltage 65 = 650V 120 = 1200V CoolSiC™ Silicon Carbide JFET I Company I = Infineon 96 J W 120 R XXX T1 Series name RDS(on) [mΩ] Device J = JFET R = RDS(on) Package Type W = TO-247 Breakdown Voltage 120 = 1200V SiC Diodes Support Expert Support for Silicon Carbide Easy Access and High Quality Application Notes, Datasheets & More www.infineon.com/sic-datasheets www.infineon.com/sic-material www.infineon.com/coolsic-datasheets www.infineon.com/coolsic-material Latest Videos www.infineon.com/sic Silicon Carbide Evaluation Boards www.infineon.com/coolsic-evaluationboard Datasheets 97 Discrete IGBT IGBT Market Leadership Through Groundbreaking Innovation and Application Focus Striving for the highest standards in performance and quality, Infineon offers a comprehensive application specific discrete IGBT portfolio that is second to none. Overview Discrete IGBTs Product Portfolio TO-252 DPAK TO-263 D2PAK TO-220 TO-220 FullPAK TO-247 TO-247 4pin TO-247PLUS Package Options NEW! Voltage Class 600V, 650V, 1100V, 1200V, 1350V, 1600V Configuration DuoPack (with diode), Single IGBT Continuous Collector Current TC = 100°C 2A - 120A New products are application specific developed to achieve highest value. New Best-in-Class Technologies and Applications Technology TRENCHSTOP™ 5 H5 F5 650V TRENCHSTOP™ 5 L5 650V Rapid Diode 650V RC-H5 650V/1200V/1350V WR5 650V RC-Drives RC-Drives Fast 600V 98 Application NEW! Discrete IGBT New Generation Reverse Conducting IGBT The newest generation of reverse conducting IGBTs has been optimized for the unique requirements of Induction Cooking applications. With a monolithically integrated reverse conducting diode, the RC-H5 family sets the industry standard for performance in soft switching applications. For single switch systems, RC-H5 is available with 1200V and 1350V blocking voltage. These 20A devices are the next generation of the successful RC-H3 family, and once again set a new industry benchmark. With up to 30% reduction in switching losses, they allow for higher system switching frequencies and improved efficiency. For half bridge designs, an entirely new family of RC-H5 650V devices was created by building on the industry leading performance of the TRENCHSTOP™ 5 and the application specific technology of earlier reverse conducting IGBTs. The result is a family of products optimized for the lowest VCE(sat) for best efficiency and thermal performance, and additionally with low Eoff for improved operation at switching frequencies up to 40kHz. IGBT Power Losses Pin = 1.8kW and fsw = 40kHz 28.6 Discrete IGBTs 30.0 23.8 25.0 21.8 Losses (W) 20.0 16.9 15.0 10.0 5.0 NEW! 0.0 IHW40N65R5 IHW40N60RF Pcond IHW40N60R Psw IHW40T60 Pdiode Features Reduced losses up to 30% Soft current turn-off waveforms for low EMI Higher blocking voltages in 650V and 1350V devices Tj(max) = 175°C 650V: Hard switching capable with commutation rugged diode Applications Induction Cooking Stoves Inverterized Microwave Ovens Induction Rice Cookers Induction Water Heaters Other Resonant Switching Applications Benefits Improved performance in systems with increased switching frequency Lowest power dissipation for best system efficiency Better thermal management for higher reliability Lower EMI filtering requirements 99 TRENCHSTOP™ 5 TRENCHSTOP™ 5 In terms of switching and conduction losses, there is no other IGBT on the market that can match the performance of the TRENCHSTOP™ 5. TRENCHSTOP™ 5 is the next generation of thin wafer technology for applications switching >10kHz. Wafer thickness has been reduced by >25%, which enables a dramatic improvement in both switching and conduction losses, whilst providing a breakthrough voltage of 650V. Translating this Best-in-Class efficiency application tests show >25% reduction in package temperature when performing a plug and play approach with Infineon’s previous Best-in-Class IGBT, the “HighSpeed 3”. Even more revolutionary, when replacing a TO-247 HighSpeed 3 IGBT with the TRENCHSTOP™ 5 in a TO-220, case temperatures are >10% lower for the TRENCHSTOP™ 5. The quantum leap of efficiency improvement provided by the TRENCHSTOP™ 5 opens up new opportunities for designers to explore. PFC Efficiency - Low Line Vin = 115V Boost Diode = Ultrafast Si 15A unless specified 96.0 95.5 Efficiency [%] 95.0 1.7% F5 + SiC, Rgoff = 20Ω 94.5 0.7% 94.0 H5 RG,off = 5Ω 93.5 H3 RG,off = 5Ω 93.0 92.5 92.0 91.5 91.0 0 100 200 300 400 500 600 700 800 Pout [W] IGP40N65F5, RG,off = 20Ω, SiC Boost Diode IGP40N65H5, RG,off = 5Ω Features 650V breakthrough voltage Compared to Infineon’s Best-in-Class “HighSpeed 3” family –– Factor 2.5 lower Qg –– Factor 2 reduction in switching losses –– 200mV reduction in VCE(sat) Co-packed with Infineon’s new “Rapid” Si-diode technology Low Coss/Eoss Mild positive temperature coefficient VCE(sat) Temperature stability of VF 100 IKW40N60H3, RG,off = 5Ω Benefits Best-in-Class efficiency, resulting in lower junction and case temperature leading to higher device reliability 50V increase in the bus voltage possible without compromising reliability Higher power density designs TRENCHSTOP™ 5 First step H5 Variation – 10kHz → 100kHz Required for UPS where full recirculating current is present Full rated diode Qrr versus VF Rapid 1 mostly chosen because of the higher Qrr. This acts snubber capacitor Rapid 2 Half rated diode H5/F5 Rapid 1 TO-220 TO-247 TO-247 4pin Welding / PFC Standard high power applications where second sourcing is more important than performance Discrete IGBTs Absolute pure performance Eon improved by up to 40% compared to TO-247 package Low VCE(sat) Variation – 50Hz → 20kHz Primary focus on UPS for full recirculating current Full rated diode L5 Rapid 2 Both diodes selected, but portfolio varies according to current class TO-247 Rapid 1 Standard high power applications where second sourcing is more important than performance TO-247 4pin Absolute pure performance Eon improved by up to 40% compared to TO-247 package, lowest conduction and switching losses Zero Current Switching Optimized Variation – 18kHz → 60kHz Universal device for ZCS turn-off Full rated diode Impressive VF & Qrr Rapid 2 WR5 TO-247 Standard high power applications 101 Consumer Drives RC-Drives and RC-Drives Fast The RC-Drives (RC-D) IGBT technology is a cost optimized solution for permanent magnet synchronous and brushless DC motors in the price-sensitive consumer drives market. The RC-Drives Fast (RC-DF) family extension was developed to provide outstanding performance at switching frequencies above 8kHz IGBT and diode were optimized to reduce losses at frequencies of 18 - 30kHz Audible noise can be reduced to absolutely silent level for high efficiency inverters operating above 16kHz Highly precise vector control techniques can be used to provide more torque in operation at low speed and high performance dynamics in the control at high speed. Furthermore, the small size of RC-Drives allows high power density designs with less system costs. Eoff vs. VCE(sat) Rs = 40Ω, Ic = 4A, Tj = 25°C and 175°C 0.30 0.25 switching frequency 30kHz Eoff (mJ) 0.20 0.15 0.10 RC-Drives Fast 8kHz -61% reduction in Eoff at 175°C 0.05 4kHz RC-Drives 0 1.5 1.6 1.7 1.8 1.9 2.0 2.1 2.2 2.3 cost 2.4 VCE(sat) (V) RC-Drives (25°C) RC-Drives (175°C) RC-Drives Fast (25°C) RC-Drives Fast (175°C) Features Optimized Eon, Eoff and Qrr for up to 20% lower switching losses Operating range from DC to 30kHz Max. junction temperature 175°C Short circuit capability of 5µs Very tight parameter distribution Best-in-Class current versus package size performance Smooth switching performance leading to low EMI levels Complete product portfolio and PSpice Models on the internet Up to 60% space saving on the PCB Higher reliability due to monolithically integrated IGBT & diode due to less thermal cycling during switching Applications RC-Drives (fsw < 4kHz) Fridge Compressors Pumps Fans Aircon Compressors Applications RC-Drives Fast (4kHz < fsw < 30kHz) Washing Machines Benefits Excellent cost/performance for hard switching applications Outstanding temperature stability Very good EMI behavior 102 General Purpose Inverters Aircon Compressors Hard Switching Topologies up to 1.0kW Automotive IGBT Discrete IGBTs TRENCHSTOP™ 60TA – Well Established and Known in the Automotive World (AEC-Q qualified) Infineon TRENCHSTOP™ 60TA IGBT technology due to combination of trench top-cell and field stop concept leads to significant improvement of static as well as dynamic performance of the device. Combination of IGBT with soft recovery Emitter Controlled-Diode further minimizes the turn-on losses. The highest efficiency is reached due to the best compromise between switching and conduction losses. Features Low VCE(sat) for low conduction losses Max. junction temperature 175°C Short circuit capability of 5µs Low EMI emissions Very soft, fast recovery anti-parallel diode Very tight parameter distribution Positive temp. coefficient in VCE(sat) Benefits Suitable for low switching frequencies High temperature capable Very good EMI behavior High ruggedness, temperature stable behavior High device reliability Applicable for high level of device paralleling Applications Main Inverter/Drive Train AUX Inverter (AirCon Compressor, PTC Heater) Motor Drives Product Portfolio TRENCHSTOP™ 60TA Technology Continuous collector current @ TC=100°C IGBT + Diode Current Rating 600V TO-263 D²PAK TO-220 TO-247 TO-247PLUS 20 A IKB20N60TA IKP20N60TA IKW20N60TA - 30 A - - IKW30N60TA - 50 A - - IKW50N60TA - 75 A - - IKW75N60TA - 100 A - - - IKQ100N60TA 120 A - - - IKQ120N60TA 103 TRENCHSTOP™ 5 Auto TRENCHSTOP™ 5 AUTO – A Revolution in the IGBT World Infineon’s brand new TRENCHSTOP™ 5 AUTO IGBT technology redefines “Best-in-Class” IGBT by providing unmatched performance in terms of efficiency for hard switching applications. It is a revolution in the IGBT world to match the market’s highest efficiency demand of tomorrow, means when highest efficiency, lower system cost and increased reliability is required, TRENCHSTOP™ 5 is the only option. It provides drastic reduction in switching and conduction losses. The TRENCHSTOP™ 5 AUTO is available in two versions - H5 (high speed) and F5 (highest efficiency). Key Features 650V blocking voltage Max. junction temperature 175°C Very low conduction and switching losses Very low junction and case temperature High power density design Mild positive temperature coefficient in VCE(sat) Benefits 50V higher blocking voltage Highest efficiency High device reliability Low temperature leads to less cooling efforts Less system costs Applications DC/DC Converter DC/AC Converter On-Board Charger Product Portfolio TRENCHSTOP™ 5 Auto Technology Continuous collector current @ TC=100°C Current Rating Single IGBT IGBT+Diode 104 650V H5 TO-247 F5 TO-247 40A IGW40N65H5A IGW40N65F5A 50A IGW50N65H5A IGW50N65F5A 40A IKW40N65H5A IKW40N65F5A 50A IKW50N65H5A IKW50N65F5A Reverse Conducting Drives Reverse Conducting Drives and Drives Fast - Qualified According to AEC Q101 Features Optimized parameters for up to 20% lower switching losses Operating range from DC to 30kHz Max. junction temperature 175°C Short circuit capability of 5µs Very tight parameter distribution Best-in-Class current versus package size performance Smooth switching performance leading to low EMI levels Benefits Excellent cost/performance for hard switching applications Outstanding temperature stability Very good EMI behavior Up to 60% space saving on the PCB Higher reliability due to monolithically integrated IGBT and diode due to less thermal cycling during switching Applications RC-DA < 8kHz Piezo Injection HID Lighting Pumps Small Drives Applications RC-DFA < 5kHz Piezo Injection HID Lighting Low Power Motor Drives Discrete IGBTs RC-Drives IGBT technology has been developed by Infineon as a cost optimized solution by offering space saving advantages due to monolithically integrated diode. Furthermore the technology provides outstanding performance for smooth switching behavior and low EMI levels even at the maximum junction temperature of 175°C. This variant enables high efficiency, especially at high speed switching up to 30kHz, while keeping the well known advantages of the RC-Drives family. It also reduces the audible noise to an absolute silent level. The complete product family offers high efficiency at reduced component size and high power density and leads to a reduction in terms of system costs. Product Portfolio Reverse Conducting Drives and Drives Fast Technology Continuous collector current @ TC=100°C Current Rating IGBT + Diode 600V RC-DA TO-252 / DPAK RC-DFA TO-252 / DPAK 3A -- IKD03N60RFA 4A IKD04N60RA IKD04N60RFA 6A IKD06N60RA IKD06N60RFA 10A IKD10N60RA IKD10N60RFA 15A IKD15N60RA IKD15N60RFA 105 IGBT Selection Tree IGBT Selection Tree Single IGBT IGBT IGBT+ Anti-Parallel Diode Soft Diode Commutation Hard Frequency Range 2kHz - 20kHz TRENCHSTOP™ >18kHz - 60kHz HighSpeed 10kHz - 100kHz HighSpeed 50Hz-20kHz LowSpeed HighSpeed 3 (H3) TRENCHSTOP™ 5 (H5/F5) Low VCE(sat) TRENCHSTOP™ 5 (L5) 2kHz - 20kHz TRENCHSTOP™ (DuoPack) 8kHz - 60kHz RC series (monolythic) 2kHz - 20kHz TRENCHSTOP™ RC-Drives (monolythic) Voltage Range 600V 600V, 650V, 1200V 650V 600V, 1200V IGpccN60H3 IGpccN120H3 IGpccN65H5 IGpccN65F5 IGpccN65L5 IHpccN60T IHpccT60.. IHpccT120.. DC/DC: Welding Inverter Full Bridge Two Transistor Forward Solar Inverter UPS 3 level NPC Topology, Inner Switches 600V, 650V, 1100V, 1200V, 1350V, 1600V 600V Part Number IGpccN60T… IGpccT120… IGpccN120T2 IHpccNvvvR2 IHpccNvvvR3 IHpccN60R/RF IHpccNvvvR5 IKpccN60R IKpccN60RF Application Conduction Loss Optimized, Hard Switching Topologies without Anti-parallel Diode AC/DC: PFC Welding UPS Solar Boost Stage AirCon 106 Solar 3 level NPC Topology, Inner Switches Welding AC Output (Al/Mg welding) Induction Heating Half Bridge Stoves Inverterized Microwave Ovens Multi-Function Printers Half Bridge Resonant (Current resonance – 600/650V) Single Switch Cookers (Voltage resonance - >650V) Conduction Loss Optimized Solar Inverter Asymmetrical Bridge Symmetrical Full Bridge Three level type I or Three level type II Converter Motor Control Three Phase Inverter Full Bridge Inverter Uninterruptable Power Supply UPS Bridge Three level type II Converter Major Home Appliances Symmetrical Full Bridge IGBT Selection Tree Automotive Frequency Range 2kHz - 20kHz TRENCHSTOP™ >18kHz - 60kHz HighSpeed 10kHz - 100kHz HighSpeed > 18kHz - 60kHz HighSpeed 50Hz - 20kHz LowSpeed DuoPack (discrete) HighSpeed 3 TRENCHSTOP™ 5 (H5/F5) RC TRENCHSTOP™ 5 (WR5) Low VCE(sat) TRENCHSTOP™ 5 (L5) 2kHz - 100kHz RC-Drives, RC-Drives Fast TRENCHSTOP™ 60TA, TRENCHSTOP™ 5 AUTO Voltage Range 600V, 1200V 600V, 1200V 650V 650V 600V 650V 650V Part Number IKpccN60dH3 IKpccN120dH3 IKpccN65dH5 IKpccN65dF5 IKpccN65dR5 IKpccN65dL5 IKpccN60RA IKpccN60RFA IHpccN60RA IKpccN60TA IKcppN65H5A IKcppN65F5A IGcppN65H5A IGcppN65F5A Discrete IGBTs IKpccN60dT IKpccT120… IKpccN120dT2 Application Conduction Loss Optimized Solar Inverter Asymmetrical Bridge Symmetrical Full Bridge Three level type I or Three level type II Converter Motor Control Three Phase Inverter Full Bridge Inverter Uninterruptable Power Supply UPS Bridge Three level type II Converter Major Home Appliances Symmetrical Full Bridge Switching Loss Optimized Solar Inverter Asymmetrical Bridge Symmetrical Full Bridge Three level type I or Three level type II Converter Motor Control Three Phase Inverter Full Bridge Inverter Uninterruptable Power Supply Three level type II Converter Major Home Appliances Symmetrical Full Bridge Welding Inverter Full Brigde Half Bridge Two Transistor Forward AC/DC: PFC Welding UPS Solar Boost Stage Battery Charger SMPS HVDC (Telecom/Data Centers) AC/DC: PFC Welding UPS Solar Boost Stage Battery Charger SMPS HVDC (Telecom/Data Centers) AirCon Washing Machine DC/DC: Welding Inverter Full Brigde Half Bridge Two Transistor Forward UPS 3 level NPC Topology, Inner Switches HID Piezo Injection Small Motor Drives Solar 3 level NPC Topology, Inner Switches PowerTrain AUX Inverter AirCon Compressor PTC Heater Welding AC Output (Al/Mag welding) OnBoard Charger (OBC) DC/DC Converter DC/AC Converter 107 IGBT Product Table TRENCHSTOP™ 5 Selection Tree IGBT+ Anti-Parallel Diode No IGBT+ Anti-Parallel Diode 650V Free Wheeling Diode (FWD) Yes 50Hz - 20kHz LowSpeed 10kHz - 100kHz HighSpeed 50Hz - 20kHz LowSpeed > 18kHz - 60kHz HighSpeed 10kHz - 100kHz HighSpeed Low VCE(sat) TRENCHSTOP™ 5 (L5) TRENCHSTOP™ 5 (H5/F5) Low VCE(sat) TRENCHSTOP™ 5 (L5) RC TRENCHSTOP™ 5 (WR5) TRENCHSTOP™ 5 (H5/F5) Corresponding best fit IGBTs Corresponding best fit IGBTs IGW30N65L5 IGP20N65H5/F5 IGP30N65H5/F5 IGP40N65H5/F5 IGW30N65H5/F5 IGW40N65H5/F5 IGW50N65H5/F5 IGZ50N65H5 IGZ75N65H5 IGZ100N65H5 IKW30N65EL5 IKW30N65NL5 IKW75N65EL5 IKZ75N65EL5 IKW30N65WR5 IKW40N65WR5 IKW50N65WR5 IKP08N65H5/F5 IKP15N65H5/F5 IKP20N65H5/F5 IKP30N65H5/F5 IKP40N65H5/F5 IKA08N65H5/F5 IKA15N65H5/F5 IKW30N65H5/F5 IKW40N65H5/F5 IKW50N65H5/F5 IKZ50N65E/NH5 IKZ75N65E/NH5 108 IGBT Product Table TRENCHSTOP™ and RC-Drives Product Portfolio 600V Product Family 4 TO-251 TO-263 D2PAK TO-220 TO-262 TO-220 FullPAK IGD06N60T TO-247PLUS IGP06N60T 10 IGB10N60T IGP10N60T 15 IGB15N60T IGP15N60T 30 IGB30N60T 50 IGB50N60T IGW30N60T IGP50N60T IGW50N60T 75 IGBT and Diode TO-247 IGU04N60T 6 Single IGBT TO-252 DPAK IGW75N60T 3 IKD03N60RF/RFA 4 IKD04N60RF/RFA IKD04N60R/RA 6 IKD06N60RF/RFA IKD06N60R/RA IKB06N60T IKP06N60T IKA06N60T 10 IKD10N60RF/RFA IKD10N60R/RA IKB10N60T IKP10N60T IKA10N60T 15 IKD15N60RF/RFA IKD15N60R/RA IKB15N60T IKP15N60T IKA15N60T IKB20N60T/TA IKP20N60T/TA 20 IKP04N60T IKW20N60T/TA 30 IKW30N60T/TA 50 IKW50N60T/TA 75 IKW75N60T/TA 100 IKQ100N60T/TA 120 IKQ120N60T/TA Discrete IGBTs Continuous collector current @ Tc=100°C TRENCHSTOP™ Product Portfolio 1200V Product Family Duo Pack Single IGBT Continuous collector current @ Tc=100°C TO-251 TO-252 DPAK TO-263 D2PAK TO-220 TO-262 TO-220 FullPAK TO-247 TRENCHSTOPTM TRENCHSTOPTM 2 8 IGW08T120 15 IGW15T120 25 IGW25T120 40 IGW40T120 60 IGW60T120 8 IKW08T120 15 IKW15T120 IKW15N120T2 25 IKW25T120 IKW25N120T2 40 IKW40T120 IKW40N120T2 109 IGBT Product Table Induction Cooking Series Product Portfolio 600V, 1100V, 1200V, 1350V & 1600V Product Families Continuous collector current @ Tc=100°C TO-251 TO-252 (DPAK) TO-263 (D2PAK) TO-220 TO-262 TO-247 600V/650V 1100V 15 1350V 1600V IHW15N120R3 IHW20N65R5 20 25 IGBT & Diode 1200V IHW20N120R3 IHW20N135R3 IHW20N120R5 IHW20N135R5 IHW25N120R2 IHW30N65R5 30 IHW30N110R3 IHW40N65R5 40 IHW30N120R3 IHW30N135R3 IHW40N120R3 IHW40N135R3 IHW30N160R2 IHW40N60R IHW40N60RF 50 IHW50N65R5 60 75 HighSpeed 2 Product Portfolio 1200V Product Family Duo Pack IGBT Continuous collector current @ Tc=100°C TO-251 TO-252 (DPAK) IGD01N120H2 1 3 3 TO-263 (D2PAK) TO-220 TO-262 TO-220 FullPAK TO-247 IGB01N120H2 IGP01N120H2 IGB03N120H2 IGP03N120H2 IGA03N120H2 IGW03N120H2 IKB03N120H2 IKP03N120H2 IKA03N120H2 IKW03N120H2 HighSpeed 3 Product Portfolio 600V Product Family IGBT Continuous collector current @ Tc=100°C TO-251 TO-252 (DPAK) TO-263 (D2PAK) TO-220 20 IGB20N60H3 IGP20N60H3 30 IGB30N60H3 IGP30N60H3 TO-247 IGW20N60H3 IGA30N60H3 IGW30N60H3 IGW40N60H3 50 IGW50N60H3 60 IGW60N60H3 75 IGW75N60H3 20 Duo Pack TO-220 FullPAK 40 100 110 TO-262 IGW100N60H3 IKB20N60H3 IKP20N60H3 IKW20N60H3 30 IKW30N60H3 40 IKW40N60H3 50 IKW50N60H3 60 IKW60N60H3 75 IKW75N60H3 IGBT Product Table HighSpeed 3 Product Portfolio 1200V Product Family TO-251 Duo Pack IGBT Continuous collector current @ Tc=100°C TO-252 (DPAK) TO-263 (D2PAK) TO-220 TO-262 TO-220 FullPAK TO-247 15 IGW15N120H3 25 IGW25N120H3 40 IGW40N120H3 15 IKW15N120H3 25 IKW25N120H3 40 IKW40N120H3 TRENCHSTOP™ 5 Product Portfolio 650V Product Family TO-251 TO-252 (DPAK) TO-263 (D2PAK) TO-220 20 IGP20N65F5/H5 30 IGP30N65F5/H5 TO-262 TO-220 FullPAK IGP40N65F5/H5 IGW50N65F5/5 IGW50N65H5A IGW50N65F5A 50 IGZ50N65H5 75 IGZ75N65H5 100 IGZ100N65H5 8 IKP08N65F5/H5 IKA08N65F5/H5 15 IKP15N65F5/H5 IKA15N65F5/H5 20 IKP20N65H5/F5 IKP30N65H5/F5 IKW30N65H5 IKW30N65WR5 IKP40N65F5/H5 40 IKW40N65F5/H5 IKW40N65WR5 IKW40N65H5A IKW40N65F5A 50 IKW50N65F5/H5 IKW50N65WR5 IKW50N65H5A IKW50N65F5A 30 Duo Pack TO-247 4pin IGW40N65F5/5 IGW40N65H5A IGW40N65F5A IGBT 40 TO-247 Discrete IGBTs Continuous collector current @ Tc=100°C IKZ50N65EH5 IKZ50N65NH5 IKZ75N65NH5 IKZ75N65EH5 65 TRENCHSTOP™ 5 Low VCE(sat) Product Portfolio 650V Product Family Continuous collector current @ Tc=100°C Duo Pack IGBT TO-251 TO-252 (DPAK) TO-263 (D2PAK) TO-220 TO-262 TO-220 FullPAK TO-247 30 lGW30N65L5 30 IKW30N65EL5 IKW30N65NL5 75 IKW75N65EL5 TO-247 4pin IKZ75N75EL5 111 IGBT Nomenclature Naming System IGBT (Products Launched After 03/2013) I K W 75 N 65 E L5 A Company I = Infineon S = Formerly Siemens Automotive Indicator F5 = Fast IGBT (~20kHz) H5 = HighSpeed 5 L5 = Low VCE(sat) Generation 5 R5 = RC Generation 5 Device G = Single IGBT H = Reverse Conducting K = Duo Pack Package Type A = TO-220-3 FullPAK B = TO-263-3 (D2PAK) D = TO-252-3 (DPAK) P = TO-220-3 U = TO-251-3 (IPAK) W = TO-247-3 Q = TO-247PLUS-3 Z = TO-247-4 Diode (for Duo Pack only) B = Emitter Controlled half rated C = Emitter Controlled full rated blank = Rapid 1 half rated E = Rapid 1 full rated M = Rapid 2 half rated N = Rapid 2 full rated R = SiC Generation 5 half rated S = SiC Generation 5 full rated W = Full rated hard switching Nominal Current [A] @ 100°C Nominal Voltage Divided by 10 (650V/10 = 65) Technology N = N-Channel P = P-Channel IGBT (Products Launched Before 03/2013) I Company I = Infineon S = Formerly Siemens Device K = IGBT + Diode (normal drives) H = optimized for soft switching applications (e.g. induction heating) G = Single IGBT D = Diode Package Type A = TO-220 FullPAK B = TO-263 (D2PAK) D = TO-252 (DPAK) P = TO-220 U = TO-251 (IPAK) W = TO-247 112 K W 40 N 120 H 3 A Automotive Generation – = Fast IGBT (~20kHz) Hχ = HighSpeed Generation (600 - 1200V) Tχ = TRENCHSTOP™ Generation (600V IGBT3) (1200V IGBT4) Rχ = Reverse Conducting RF = Reverse Conducting Fast F = HighSpeed FAST 5 Rχ = Rapid Diode Generation Nominal Voltage Divided by 10 (1200V/10 = 120) Technology N = N-Channel T = TRENCHSTOPTM E = Emitter Controlled Diodes (for diode only) Nominal Current (@ 100°C) [A] Discrete IGBTs IGBT Support Expert Support for Discrete IGBT Easy Access and High Quality Application Notes, Datasheets & More www.infineon.com/igbt-datasheets www.infineon.com/igbt-material www.infineon.com/discrete-automotive-igbt www.infineon.com/latest-discrete-packages Latest Videos www.infineon.com/igbtdiscretes New Releases www.infineon.com/igbt-newreleases Datasheets 113 Silicon Power Diodes Silicon Power Diodes The Rapid Diode family complements Infineon’s existing high power 600V/650V diode portfolio by filling the gap between SiC diodes and previously released emitter-controlled diodes. They represent a perfect cost/performance balance and target high efficiency applications switching between 18kHz and 100kHz. Rapid 1 and Rapid 2 diodes are optimized to have excellent compatibility with CoolMOS™ and high speed IGBT (Insulated Gate Bipolar Transistor) such as the TRENCHSTOP™ 5 and HighSpeed 3. Emitter Controlled Diodes 0Hz Rapid 1 Rapid 2 18kHz 40kHz SiC 100kHz>100kHz The Rapid 1 Diode Family Rapid 1 is forward voltage drop (VF) optimized to address low switching frequency applications: Optimized for applications switching between 18kHz and 40kHz, for example Air Conditioner and Welder PFC stages 1.35V temperature-stable forward voltage (VF) Lowest peak reverse recovery current (Irrm) Reverse recovery time (trr) < 100ns High softness factor The Rapid 2 Diode Family Rapid 2 is Qrr/trr optimized hyperfast diode to address high speed switching applications: Optimized for applications switching between 40kHz and 100kHz typically found in PFCs in high efficiency Switch Mode Power Supplies (SMPS) and Welding Machines. Lowest reverse recovery charge (Qrr): VF ratio for Best-in-Class performance Lowest peak reverse recovery current (Irrm) trr < 50ns High softness factor VF - Qrr Trade-off, Rapid 1 diF/dt = 1000A/us, Rapid 2 diF/dt = 300A/us PFC Efficiency @ 60kHz – Vin = 230V 900 IDW30E65D1 800 Comp A 700 Comp B Efficiency [%] Qrr [nC] 600 500 400 97.4 98.0 97.2 97.8 97.0 97.6 96.8 97.4 96.6 96.4 96.2 200 96.0 IDP08E65D2 Comp C 1.3 IDP08E65D2 Comp D 1.5 1.6 1.7 VF [V] 1.8 1.9 2.0 2.1 2.2 2.3 97.0 96.8 96.6 Comp. F 96.4 95.6 1.4 97.2 Comp. S 95.8 0 114 98.2 300 100 PFC E 97.6 Efficiency [%] 1000 96.2 0 100 200 300 400 Output Power [W] 500 600 700 800 0 200 400 Si Power Diodes Product Table Rapid 1 Diodes 650V Product Family 8A IDP08E65D1 15A IDP15E65D1 TO-220 (Common Cathode) TO-247 TO-247 (Common Cathode) IDV20E65D1 20A 30A TO-220 FullPAK Silicon Power Diodes TO-220 Continuous Current Ic Tc=100°C IDP30E65D1 IDW30E65D1 IDW30C65D1 IDW40E65D1 40A 60A IDW60C65D1 75A IDW75D65D1 80A IDW80C65D1 Rapid 2 Diodes 650V Product Family Continuous Current Ic Tc=100°C TO-220 TO-220 FullPAK 8A IDP08E65D2 IDV08E65D2 15A IDP15E65D2 IDV15E65D2 20A IDP20E65D2 30A IDP30E65D2 40A IDP40E65D2 80A IDV30E65D2 TO-220 (Common Cathode) TO-247 TO-247 (Common Cathode) IDW15E65D2 IDP20C65D2 IDW20C65D2 IDP30C65D2 IDW30C65D2 IDW40E65D2 IDW80C65D2 115 Si Power Diodes Product Table Emitter Controlled Diodes 600V and 1200V Product Families TO-252 (DPAK) 600V Continuous Current Ic Tc=100°C 6 IDD06E60 9 IDD09E60 15 IDD15E60 TO-263 (D2PAK) 30 TO-220 Real 2pin IDB15E60 IDP15E60 IDB30E60 IDP30E60 IDW30E60 IDP45E60 45 50 IDW50E60 75 IDW75E60 IDW100E60 100 1200V TO-247 IDP12E120 12 IDP18E120 18 30 IDB30E120 IDP30E120 Naming System Silicon Power Diodes I Company I = Infineon Device D = Diode Package Type P = TO-220 V = TO-220 FP W = TO-247 Nominal Current (@ 100°C) [A] 116 D W 75 E 65 D1 D1 = Rapid 1 D2 = Rapid 2 Nominal Voltage Divided by 10 (650V/10 = 65) Technology E = Std. Diode configuration C = Common Cathode D = Dual Anode A = Tandem Silicon Power Diodes Silicon Diodes Support Expert Support for Si Power Diodes Easy Access and High Quality Application Notes, Datasheets & More www.infineon.com/rapiddiodes-material www.infineon.com/rapiddiodes-datasheets www.infineon.com/ultrasoftdiodes-material www.infineon.com/ultrasoftdiodes-datasheets Latest Videos www.infineon.com/rapiddiodes Datasheets 117 Power Management ICs Power Management ICs Technology Leadership in Power Supply AC/DC Power Management ICs PWM Controller PFC Controller CCM PFC Stand-alone PWM Fixed Frequency CoolSET™ (Continuous Conduction Mode) Fixed Frequency ICE2PCS02G (65kHz) ICE2PCS03G (100kHz) ICE2PCS04G (133kHz) Adjustable Frequency ICE2PCS01G (50kHz - 250kHz) ICE2PCS05G (20kHz - 250kHz) ICE3PCS01G (OVP+Brown-out) ICE3PCS02G (OVP) ICE3PCS03G (Brown-out) DCM PFC Fixed Frequency (FF) ICE3AS03LJG (100kHz) ICE3BS03LJG (65kHz) ICE3GS03LJG (130kHz) Quasi Resonant (QR) ICE2QS02G ICE2QS03G Half-bridge (HB) LLC Resonant ICE1HS01G-1 ICE2HS01G Combi (PFC+PWM) (Discontinuous Conduction Mode) TDA4862(G) TDA4863(G) TDA4863-2(G) 118 TTR Combi ICE1CS02 ICE1CS02G 650V F3/F3R CoolSET™ ICE3A/B(R)xx65Jx ICE3RBRxx65JZ 800V F3R CoolSET™ ICE3A/BRxx80Jx ICE3ARxx80CJZ ICE3ARxx80VJZ Quasi-Resonant CoolSET™ 650V CoolSET™ ICE2QRxx65 800V CoolSET™ ICE2QRxx80(G) DCM PFC ICs Power Factor Correction and Combo Controller Discontinuous Conduction Mode PFC ICs zero crossing detector TDA4862 / TDA4862G TDA4863-2/G Power Factor Controller (PFC) IC for high-power factor and active harmonic filter IC for sinusoidal line-current consumption Power factor approaching 1 Controls boost converter as an active harmonics filter Internal start-up with low current consumption Zero current detector for discontinuous operation mode High current totem pole gate driver Trimmed +/-1.4% internal reference Undervoltage lock out with hysteresis Very low start-up current consumption Pin compatible with world standard Output overvoltage protection Current sense input with internal low pass filter Totem pole output with active shutdown during UVLO Junction temperature range -40°C to +150°C Available in DIP-8 and SO-8 packages Power Factor Controller IC for high-power factor and low THD additional features to TDA4862 Reduced tolerance of signal levels Improved light load behavior Open loop protection Current sense input with leading edge blanking LEB Undervoltage protection Power ICs TDA486x 119 CCM PFCs Continuous Conduction Mode PFC ICs ICE2PCSxx 2nd Generation Continuous Conduction Mode (CCM) Power Factor Correction IC Features Fulfills Class D requirements of IEC 61000-3-2 Lowest count of external components Adjustable and fixed switching frequencies Frequency range from 20kHz to 250kHz Versions with brown-out protection available Wide input range supported Enhanced dynamic response during load jumps Cycle by cycle peak current limiting Integrated protections OVP, OCP DIP-8 and DSO8 Leadfree, RoHS compliant 2nd Generation Continuous Conduction Mode (CCM) Power Factor Correction IC Product Portfolio Product 120 Frequency – fSW Current Drives Package ICE2PCS01G 50kHz-250kHz 2.0A DSO-8 ICE2PCS02G 65kHz 2.0A 2.0A ICE2PCS03G 100kHz ICE2PCS04G 133kHz 2.0A ICE2PCS05G 20kHz-250kHz 2.0A CCM PFCs 3rd Generation Continuous Conduction Mode (CCM) Power Factor Correction IC Features Fulfills Class D requirements of IEC 61000-3-2 Integrated digital voltage loop compensation Boost follower function Bulk voltage monitoring signals, brown-out Multi protections such as Double OVP Fast output dynamic response during load jump External synchronization Extra low peak current limitation threshold SO-8 and SO-14 Leadfree, RoHS compliant Product Frequency – fSW Current Drives Features Package ICE3PCS01G Adjustable 0.75A OVP+Brown-out SO-14 ICE3PCS02G 0.75A OVP SO-8 ICE3PCS03G 0.75A Brown-out SO-8 CCM PFC by feature ICE2PCS01(G) ICE2PCS05(G) Digital control voltage loop Variable frequency ICE2PCS02(G) ICE2PCS03(G) ICE2PCS04(G) – – ü Synchronous frequency – ICE3PCS03G ICE3PCS02G ICE3PCS01G ü ü ü ü ü ü ü ü ü Open loop protection ü ü ü ü ü Low peak current limit -1V -1V -0,4V -0,4V -0,2V Brown out protection – ü ü – ü Over voltage protection ü ü ü ü ü ü ü Second over voltage protection – PFC enable function – ü Boost follower mode – ü 5V regulator – ü Power ICs Fixed Frequency PWM IC and CoolSET™ Product Portfolio 121 Combi CCM PFC IC/PWM IC Combination of Continuous Conduction Mode PFC with Two-Transistor Forward PWM IC ICE1CS0x/G Pre-short protection Trimmed reference voltage +/-2.5% (+/-2% at 25°C) BiCMOS technology for wider VCC range Power Factor Correction Block Fulfills Class D requirements of IEC 61000-3-2 Fixed switching frequency (sync to half PWM freq.) AC brown-out protection Average current control Max. duty cycle of 95% Enhanced dynamic response for fast load response Unique soft-start to limit start up current Over-voltage protection Product Frequency – fSW Current Drives ICE1CS02 PFC=65kHz PWM=130kHz 2.0A DIP-16 2.0A DSO-16 ICE1CS02G 122 Pulse-Width-Modulation Block Fixed switching frequency Option for external control synchronization Built in soft start for higher reliability Max duty cycle 47% or 60% Overall tolerance of current limiting <+/-5% Internal leading edge blanking Slope compensation Fast, soft switching totem pole gate drive (2A) SO-16 and DIP-16 Pb-free lead plating and RoHS compilant All protection features available Package LLC Controller ICs Resonant LLC Half-Bridge Controller IC LLC Resonant (No SR) ICE1HS01G-1 Novel and simple design (12 components + HB driver) Minimum operating frequency is adjustable externally Burst mode operation for output voltage regulation during no load and/or bus over-voltage Multiple protections in case fault Input voltage sense for brown-out protection Open loop/over load fault detection by FB pin with auto-restart and adjustable blanking/restart time Power ICs Frequency shift for over-current protection Lead Free, RoHS compliant package DSO-8 package Product Frequency – fSW Dead Time(ns) Current Drives Package ICE1HS01G-1 30kHZ~600kHz 380 1.5A DSO-8 123 LLC Controller ICs Resonant LLC Half-Bridge Controller IC with Integrated Sychronised Rectifier Control LLC Resonant + SR ICE2HSO1G Novel LLC/SR operation mode and controlled by primary side controller Multiple protections for SR operation Tight tolerance control Accurate setting of switching frequency and dead time Simple system design Optimized system efficiency Multiple converter protections: OTP, OLP, OCP, latch-off enable External disable for either SR switching or HB switching Lead free, RoHS compliant package DSO-20 package 124 Product Frequency(SW) Dead Time(ns) Current Drives Package ICE2HS01G 30kHz~1MHz 100~1000 0.3A DSO-20 LLC Controller ICs Package Switching frequency range ICE1HS01G-1 ICE2HS01G DSO-8 DSO-20 up to 600kHz up to 1MHz LLC softstart ü ü LLC burst mode ü ü Adjustable minium frequency ü ü Over load/open loop protection ü ü Mains undervoltage protection with hysteresis Over current protection ü ü 2-level 3-level Drive signal for Synchronous Rectification – ü Adjustable deadtime – ü External latch-off and OTP Target application – ü LCD-TV, Audio, etc. Server, PC, LCD-TV, etc. Power ICs LLC Half-Bridge Controller IC 125 Climate Saver Systems Climate Saver 80 PLUS® and 80 PLUS® Bronze 12V 5V 3V3 PFC / PWM 5V 80 PLUS® and 80 PLUS® Bronze PFC Block ICE1CS02/G CoolSETTM PWM Block ICE3AR10080JZ/CJZ Standby Block CoolSET™ ICE3AR4780JZ ICE3AR2280JZ/CJZ ICE3AR0680JZ ICE3AR4780CJZ Climate Saver 80 PLUS® Silver DC/DC 5V DC/DC 3V3 12V PFC 80 PLUS® Silver PFC Block PWM Block ICE2PCS01G ICE2PCS02G ICE1HS01G-1 ICE3AR4780JZ ICE3AR2280JZ/CJZ ICE3AR0680JZ ICE2QR4765 ICE2QR1765 ICE2QR0665 ICE3AR4780CJZ 126 5V CoolSETTM ICE3AR10080JZ/CJZ Standby Block CoolSET™ PWM Climate Saver Systems Climate Saver 80 PLUS® Gold Climate Saver 80 PLUS® Platinum Certification for Infineon's Silverbox reference design 5V DC/DC 3V3 DC/DC 12V PFC PWM 5V CoolSETTM ICE3PCS01G PFC Block ICE3PCS02G ICE3PCS03G PWM Block 80 PLUS® Platinum Certification for Infineon's Silverbox reference design ICE3PCS01G PFC Block ICE2HS01G ICE3AR10080JZ/CJZ ICE3PCS03G PWM Block ICE3AR4780JZ Standby Block CoolSET™ ICE3AR2280JZ/CJZ ICE3AR0680JZ ICE3BR2280JZ ICE3PCS02G ICE2HS01G ICE2QR4780Z Standby Block CoolSET™ Power ICs 80 PLUS® Gold ICE2QR2280Z - 1 ICE2QR0680Z ICE2QR2280G-1 ICE3BR0680JZ ICE3AR4780CJZ www.infineon.com/silverbox 127 Isolated AC/DC Isolated AC/DC Quasi-Resonant PWM IC and CoolSET™ Features zero crossing detector CoolSETTM Integrated CoolMOS™ with Auto restart mode for VCC under- Peak power limitation with input startup cell Quasi-resonant operation with digital frequency reduction High average efficiency over wide load range Stable operation without jittering/ audible noise problem Active burst mode operation for very low standby losses (to achieve standby power <50mW) voltage/over-voltage protection Auto restart mode for open-loop and output overload protection Auto restart mode for over-temperature protection Latch-off mode for output overvoltage, short-winding BiCMOS technology (controller) for wide VCC operation and low IC power consumption voltage compensation Minimum switching frequency limitation (no audible noise on power units on/off) DIP and DSO package (for controllers and CoolSET™ ) Quasi-resonant PWM IC and 650V CoolSET™ Pout1) (85 … 265VAC) / RDS(on) Package 14~15W 23~26W 34W 38~42W 4.7Ω 1.7Ω 1.0Ω 0.6Ω PWM Only 650V Depletion CoolMOS™ DIP-7 ICE2QR4765Z ICE2QR1765Z DIP-8 ICE2QR4765 ICE2QR4765-T ICE2QR1765 ICE2QR0665 ICE2QR4765G ICE2QR1765G ICE2QR0665G DSO-8 ICE2QR1065Z ICE2QR0665Z ICE2QS02G ICE2QS03G DSO-12 Quasi-resonant CoolSET™ 800V Pout1) (85 … 265VAC) / RDS(on) 18W 4.7Ω Package DIP-7 DSO-12 1) 128 24W 47W 2.2Ω 0.6Ω 800V Depletion CoolMOS™ ICE2QR4780Z ICE2QR2280Z ICE2QR2280Z-1 ICE2QR2280G ICE2QR2280G-1 Output power assume 78~83% efficiency. Ta=50°C, Tj=125°C and no copper area for 650V device and 232mm2 copper area for 800V device. ICE2QR0680Z Isolated AC/DC Fixed Frequency PWM IC and CoolSET™ Features CoolSETTM Active burst mode to achieve DCM, CCM Fixed softstart time the lowest standby power requirements < 50mW Optional latched off mode (L) to increase robustness and safety of the system Adjustable blanking window for high load jumps to increase reliability Startup cell switched off after start-up 65kHz/100kHz/130kHz internally fixed switching frequency Over-temperature, over-voltage, short-winding, overload and openloop, VCC under-voltage, brown-out protections, fast AC reset, input over-voltage protection Overall tolerance of current limiting < +/-5% Internal leading edge blanking time Max. duty cycle 72% DIP, DSO and FullPAK packages Fixed Frequency PWM IC and CoolSET™ 650V Pout1) (85 … 265VAC) / RDS(on) 13~14W 18W 24~25W 34W 39~40W 61 ~138W 6.5Ω 4.7Ω 3.0Ω 1.7Ω 1.0Ω 0.6Ω 2.5Ω/1.4Ω/1.0Ω/0.6Ω PWM Only 650V Depletion CoolMOS™ DIP-7 ICE3RBR4765JZ DIP-8 DSO-8 ICE3B0365J ICE3B0365J-T ICE3BR4765J ICE3B0365JG ICE3BR4765JG ICE3RBR1765JZ ICE3A1065ELJ ICE3BR1765J ICE3RBR0665JZ ICE3A2065ELJ ICE3BR1065J ICE3BR0665J Power ICs Package 11~12W ICE3AS03LJG ICE3BS03LJG ICE3GS03LJG DSO-12 ICE3BR2565JF (61W) (2.5Ω) ICE3BR1465JF (77W) (1.4Ω) ICE3BR1065JF (93W) (1.0Ω) ICE3BR0665JF (138W) (0.6Ω) TO-220 FullPAK Fixed Frequency PWM IC and CoolSET™ 800V Pout1) (85 … 265VAC) / RDS(on) 11W 16W 22W 30W 37W 43W 10.0Ω 4.7Ω 2.2Ω 1.5Ω 1.0Ω 0.6Ω Package DIP-7 1) 800V Depletion CoolMOS™ ICE3AR10080JZ ICE3AR10080JZ-T ICE3AR10080CJZ ICE3AR4780JZ ICE3AR4780VJZ ICE3AR4780CJZ ICE3AR2280JZ ICE3AR2280JZ-T ICE3AR2280CJZ ICE3AR2280VJZ ICE3BR2280JZ ICE3BR2280JZ-T ICE3AR1580VJZ ICE3AR1080VJZ ICE3AR0680JZ ICE3AR0680VJZ ICE3BR0680JZ Output power assume 76~83% efficiency. Ta=50°C, Tj=125°C and no copper area 129 Isolated AC/DC Fixed Frequency PWM IC FF PWM IC ICE3AS03LJG ICE3BS03LJG Package ICE3GS03LJG DSO-8 Operating temperature Switching frequency -25°C ~ 130°C 100kHz 65kHz Max VCC voltage 130kHz 27V VCC on/off threshold Soft start time 18V / 10.5V 10ms 20ms Gate drive capability 10ms -0.17A / 0.39A Jitter feature for low EMI √ Modulated gate drive √ Active burst mode √ Over load/Open loop Auto restart VCC under voltage/ Short opto-coupler Auto restart Short winding/Short diode latch-off VCC over voltage latch-off Over temperature latch-off External protection enable pin latch-off Quasi-Resonant PWM IC Feature Package Operating temperature Startup cell VCC on/off Power saving during standby Digital Frequency reduction for high average efficiency ICE2QS03G DSO-8 DSO-8 -25°C ~ 130°C -40°C ~ 130°C – ü 12V / 11V 18V / 10.5V – Active Burst Mode with fsb = 52kHz ü ü OLP blanking time Adjustable Fixed Auto restart timer Setting with external components Through VCC charging/discharging Adjustable through ZC resistor Adjustable through ZC resistor Yes with VZCOVP=4.5V Yes, with VZCOVP=3.7V Maximum input power limitation Adjustable output overvoltage protection with Latch mode 130 ICE2QS02G brown-out feature ü – Target application Aux-Power Supply to VCC Eg. LCD TV multi/main, Audio main, PDP TV multi/address Self-Power Supply to VCC e.g. Notebook/Tablet Adapters, LCD TV Mulit, CRT TV, Audio, DVD, Smart Meter, Industrial applications Isolated AC/DC Quasi-Resonant CoolSET™ 650V CoolSET™ Package DIP-8/DIP-7/DSO-16/12 CoolMOS™ rating RD(on) Output power 2) Operating temperature ICE2QRxx65-T ICE2QRxx80Z/G DIP-8 DIP-7 / DSO-16/12 650V1) 4.7Ω 0.65/2.2/4.7Ω 14 ~ 42W 15W 18 ~ 47W -25°C ~ 130°C -40°C ~ 130°C 18V / 10.5V 24W 18V / 9.85V Active Burst Mode with fsb = 52kHz Digital Frequency Reduction for high average efficiency √ OLP blanking time Fixed Auto restart timer Through VCC charge/disscharge Maximum input power limitation Adjustable through ZC resistor Adjustable output overvoltage protection with latch mode Yes, with VZCOVP = 3.7V ICE2QR4765 ICE2QR4765Z ICE2QR4765G ICE2QR1765 ICE2QR1765Z ICE2QR1765G ICE2QR1065Z ICE2QR0665 ICE2QR0665Z ICE2QR0665G 2.2Ω -25°C ~ 130°C Power Saving during standby Product available DIP-7 / DSO-16/12 800V 0.65/1.0/1.7/ 4.7Ω VCC on/off ICE2QRxx80Z/G-1 ICE2QR4765-T ICE2QR4780Z ICE2QR2280Z ICE2QR2280G ICE2QR0680Z Power ICs ICE2QRxx65/Z/G 800V CoolSET™ ICE2QR2280Z-1 ICE2QR2280G-1 DFR= Digital Frequency Reduction, PPR= Peak Power Limitation/Control 1) Output power assume 78~83% efficiency. Ta =50°C, Tj =125°C and no copper area for 650V device and 232mm2 copper area for 800V device. 131 Isolated AC/DC Fixed Frequency CoolSET™ 650V CoolSET™ F3(Jitter) ICE3Bxx65J(G) Package F3( Latch & Jitter) ICE3Axx65ELJ F3R ICE3BRxx65J(G) DIP-8, DSO-16/12 DIP-8 11W ~ 12W 18W ~ 34W Output power range 1) MOSFET (rugged avalanche capability) 67kHz 100kHz Max Vcc voltage 18V / 10.3V ü 11W -40°C 65kHz 65kHz ü ü – by CSOFTS 20ms by CSOFTS 1 level Auto restart Auto restart Vcc over voltage Auto restart Latch Auto restart Over temperature Auto restart Latch Auto restart – Latch Auto restart brown-out – Input OVP – Fast AC reset – Slope compensation for CCM mode Product available (by CSOFTS) – Vcc under voltage/ short opto-coupler External protection enable pin 67kHz 18V / 10.3V ü Over load/Open loop 132 DIP-8 13W ~ 40W 18V / 10.5V (by CSOFTS) Active burst mode selection 1) DIP-7 13W ~ 40W 27V Vcc on/off threshold Soft start time DIP-8, DSO-16/12 -25°C Switching frequency Modulated gate drive F3(Jitter) ICE3B0365J-T 650V Min. operating temperature Jitter feature for low EMI F3R ICE3RBRxx65JZ – – ICE3B0365J ICE3B0365JG Output power assume 76~83% efficiency. Ta=50°C, Tj=125°C and no copper area ICE3A1065ELJ ICE3A2065ELJ ICE3BR4765J ICE3BR1765J ICE3BR1065J ICE3BR0665J ICE3BR4765JG ICE3RBR4765JZ ICE3RBR1765JZ ICE3RBR0665JZ ICE3B0365J-T Isolated AC/DC 800V CoolSET™ F3R 800V ICE3ARxx80JZ F3R 800V ICE3BRxx80JZ F3R CCM 800V ICE3ARxx80CJZ F3R 800V ICE3ARxx80JZ-T F3R 800V ICE3BRxx80JZ-T F3R 800V ICE3ARxx80VJZ 11W ~ 22W 11W 11W ~ 43W 100kHz 65kHz DIP-7 11W ~ 43W 11W ~ 22W 800V -25°C 100kHz 65kHz -40°C 100kHz 100kHz 27V 17V / 10.5V ü Power ICs YES (with 50Ω gate turn-on resistor) 10ms 4 levels 3 levels 4 levels Auto restart Auto restart Auto restart Auto restart with hysteresis Auto restart ICE3AR10080JZ ICE3AR4780JZ CE3AR2280JZ ICE3AR0680JZ Latch – – – ü – ü – ü ICE3BR2280JZ ICE3BR0680JZ Auto restart ü ICE3AR10080CJZ ICE3AR4780CJZ ICE3AR2280CJZ – – ICE3AR10080JZ-T ICE3AR2280JZ-T ICE3BR2280JZ-T ICE3AR4780VJZ ICE3AR2280VJZ ICE3AR0680VJZ ICE3AR1080VJZ ICE3AR1580VJZ 133 Non-Isolated DC/DC Non-Isolated DC/DC MOSFET Gate Driver IC The new OptiMOS™ Driver products PX3517 and PX3519 are high speed Drivers, designed to drive a wide range of dual high side and low side n-channel power MOSFETs in applications such as Computing and Telecom Point-of-Load (PoL). Combining the new devices with the Primarion/Infineon Digital Multi-Phase Controllers IC family and Infineon N-Channel MOSFETs, the new devices form a complete core-voltage regulator solution for advanced micro and graphic processors as well as Point-of-Load applications. To tailor the efficiency of the system based on the customer conditions and needs, the OptiMOS™ Driver devices provide the capability of driving the high-side gate and low-side gate with a variable gate driving voltage ranging from 4.5V up to 8V. General Features High frequency operation up to 1.2MHz Includes bootstrap diode Wide VCC input voltage range from 4.5V to 8V Adaptive shoot through protection Capability to drive MOSFET at 50A continuous current Compatible with standard + 3.3V PWM controller ICs per phase Tri-state PWM input functionality Wide input voltage range: up to 16V RoHS compliant Low power dissipation Application Diagrams PX3517 offers a thermal warning report function. RT PX3519 features a gate disable pin (EN) for low power consumption. VCC BOOT PVCC EN BOOT 3.3V THW# HS Driver Level Shifter UGATE 100K 10K UVLO 3.3V 4K25 Input Logic 3 State HS Logic to GND 4K 25 - PWM PVCC LS Logic 4K0 Logic Unit LS Driver Input Logic 3 State PWM LGATE 10K PHASE Shoot Through Protection Unit HS Logic - LS Logic 4K Logic Unit GND 134 10K PHASE Shoot Through Protection Unit UGATE 3.3V Thermal Sense Cell VCC HS Driver Level Shifter VCC LGATE LS Driver 10K GND Gate driver PX3517 PX3519 Package 3mm x 3mm TDSON-10 3mm x 3mm VDSON-8 RoHS compliant ✓ ✓ Max. junction temperature -25°C to 125°C -25°C to 125°C Supply voltage and driving voltage, VCC +4.5V to 8V +4.5V to 8V Boot to GND 30 30 PWM inputs tri-state compatibility tri-state compatibility Quiescent current IQ 660µA 780µA Features thermal warning driver enable pin Non-Isolated DC/DC 6 x 6 IQFN High-Performance DrMOS (Driver+MOS) TDA21220 Features Intel compliant DrMOS, Power MOSFET and Driver Extremely robust switch node -10V ... 25V in noisy applications Includes active PMOS Adaptive gate drive for shoot through protection 5V high and low side driving voltage Compatible to standard PWM controller ICs with 3.3V and 5V logic Tri-State functionality Small package: IQFN-40 (6 x 6 x 0.8mm3) RoHS compliant (Pb Free) in one package For synchronous buck – step-down voltage applications Wide input voltage range from 5V to 16V High efficiency Extremely fast switching technology for improved performance at high switching frequencies Remote driver disable function SMOD-switching modulation of low side MOS DrMOS Application Diagram VCIN UVLO VDRV BOOT Level Shifter VIN GH HS Driver DISB# VSWH HS Logic VCIN Shoot Through Protection Unit PWM LS Logic SMOD# Power ICs Input Logic 3-State LS Driver IC Driver CGND GL PGND TDA21220 Input voltage range 5V to 16V SMOD function supported Thermal warning/shutdown - Max. average load current 50A MOSFET breakdown voltage 25V PWM levels compatible +3.3V / +5V (tolerant) Swhoot through protection included 135 Non-Isolated DC/DC DrBlade™ The Revolutionary Next Packaging Generation Infineon has launched the revolutionary Blade chip embedding technology. DrBlade™ contains the latest generation low voltage DC/DC Driver technology and OptiMOS™ MOSFET devices. Features Compatible to Intel® VR12 Driver and MOSFETs module (DrMOS) functionality High current capability up to 60A Capable of operating up to 1.2MHz switching frequency Fast switching technology for improved performance (>95% peak efficiency) Small package size and low profile: 6.6x4.5x0.6m³ Optimized footprint for DC/DC converter layout and improved cooling to the PCB Low thermal resistance to the top side RoHS compliant and halogen free Compatible to standard +3.3V PWM controller Applications High performance Desktop, Notebook and Server DC/DC converters Single Phase and Multiphase DC/DC Point-of-Load (PoL) converters CPU/GPU voltage regulation in Desktop Graphics Cards, DDR Memory, Graphic Memory High Power Density Voltage Regulator Modules (VRM) Telecom VR TDA21320/ TDA21321 Features Temperature reporting and over temperature protection High side short protection Over-current protection Shoot-through protection Under voltage lockout Boot switch included Low side-off function TDA21320 136 TDA21321 Input voltage 16V 16V SMOD function included included Temperature reporting and overtemperature protection included included 30A Max average load current 60A Maximum MOSFET BVDSS voltage 25V 25V PWM levels +3.3V +3.3V Shoot through protection included included Non-Isolated DC/DC Digital Controllers for Point-of-Load Power Management Infineon’s Digital Multi-phase and Multi-rail controllers provide power for today’s medium and high current PoL applications used in Telecom/Datacom and Server and Storage environments. Infineon’s Digital Controller family enables OEMs and ODMs to improve efficiency and total cost of ownership while increasing power density and optimizing the total system footprint of the voltage regulator. The PX7247, PX7241, PX7143, PX7242 and PX7141 are the first products out of our 4th generation digital controller family and support up to 2 rails with 1-6 phases on individual rails. The I2C/ PMBus interface connects the digital controllers to the application system and provides real time telemetry information, monitoring and control capabilities. The digital controllers are fully configurable through our PowerCode™ graphical user interface that allows for easy to use and simplified design optimization. Multiple Phase Configurations are Supported for Best Power Optimization: Feature Controller Family Configurable output rails Part No. PMBus Phase configuration Main Sub configurations Vout_max Switching frequency Operating temperature range VQFN Package Dual /Single Rail Dual Rail Single Rail Dual Rail PX7247HDN PX7241HDN PX7143HDM PX7242HDM Single Rail PX7141HDM 6+1 3+3 3ph 1+1 1ph 6+0, 5+1+, 5+0, 4+1 3+2, 3+1, 2+2+, 2+1 2ph - - 5V 5V 5V 5V 5V Up to 2 MHz Up to 2 MHz Up to 2 MHz Up to 2 MHz Up to 2 MHz -0…85°C -0…85°C -0…85°C -0…85°C -0…85°C 48-lead (6 x 6) 0.4mm pitch 48-lead (6 x 6) 0.4mm pitch 40-lead (5 x 5) 0.4mm pitch 40-lead (5 x 5) 0.4mm pitch 40-lead (5 x 5) 0.4mm pitch Advantages of a Digital Controller Power ICs Protection features include a set of sophisticated over-voltage, under-voltage, over-temperature, and over-current protections. PX7247, PX7241, PX7143, PX7242 and PX7141 also detect and protect against an open circuit on the remote sensing inputs. These attributes provide a complete and advanced protection feature set for microprocessor, DSP, FPGA or ASIC power systems. Accurate current sense telemetry is achieved through internal calibration that measures and corrects current sense offset error sources upon startup. Programmable temperature compensation provides accurate current sense information even when using DCR current sense. 137 Non-Isolated DC/DC Typical Point-of-Load Application PWM OFF +12V RB +5V R1 +3.3V VDD PX7241HIN VR_EN RESET TDA21320 DrBlade™ 2 BOOT PHASE IMON IMONREF CGND PWM TMON SW VIN VDRV TDA21320 DrBlade™ 2 BOOT PHASE CBOOT L CBOOT LOAD1 PGND IMON IMONREF CGND PWM2 PWM TMON SW ISEN2N OFF ISEN2P VIN COUT PWM1 BVR_READY ISEN1P RB TDA21320 DrBlade™ 2 BOOT PHASE PWM3 VDRV SADDR_M ISEN3N VCIN IMON IMONREF CGND SADDR_L ISEN3P PWM TMON SW SCL L PGND VCIN VCIN ISEN1N SDA RB SW TSEN VR_READY I2C Interface VDRV OFF VINSEN R2 VIN TMON DR_EN L CBOOT PGND Rext VSENP Cext VSENN BTSEN FAULT1 IMON/FAULT2 OFF BPWM1 RB BISEN1N BISEN1P VIN VDRV TDA21320 DrBlade™ 2 BOOT PHASE CBOOT PGND VCIN IMON IMONREF CGND BISEN3N PWM TMON SW BISEN3P OFF BDR_EN VIN BPWM2 L BISEN2N BISEN2P VD15_BP1 VD15_BP2 VD15 BPWM3 Rext BVSENP RB Cext GND VDRV BOOT PHASE CBOOT PGND VCIN IMON IMONREF CGND PWM TMON SW RB VIN VDRV VCIN TDA21320 DrBlade™ 2 IMON BOOT PHASE PGND IMONREF CGND LOAD2 COUT BVSENN OFF 138 TDA21320 DrBlade™ 2 L L CBOOT Power ICs Support Expert Support for Power ICs Easy Access and High Quality Application Notes, Datasheets & More www.infineon.com/acdc www.infineon.com/dcdc www.infineon.com/coolset www.infineon.com/drblade www.infineon.com/drmos Power Management ICs Evaluation Boards www.infineon.com/powercontrol.evalboards www.infineon.com/coolset.evalboards www.infineon.com/coolsetqr.evalboards Datasheets 139 Lighting ICs Lighting ICs Ballast Control IC for Fluorescent Lamp Ballast Control ICs from Infineon integrate all functions required to operate FL lamps such as preheat-, ignition- and run-mode and protection features. Digital mixed-signal power control is employed enabling speedy, cost effective and stable ballast designs with a minimum number of external components. Reliable and robust high voltage isolation is achieved using Infineon’s proprietary Coreless Transformer Technology (CLT). Integrated high performance PFC stage Intelligent digital/mixed signal power control Integrated high voltage half bridge driver All parameters set using only resistors Highly accurate timing and frequency control over a wide temperature range PFC Controller Ballast Controller HV-Driver 140 Ballast Control ICs ICB2FL01G Infineon’s 2nd Generation Ballast Controller ICB2FL01G is designed to control a fluorescent lamp ballast including Power Factor Correction (PFC) Lamp inverter control and High voltage level-shift half bridge driver with Coreless Transformer Technology min. Operating voltage range Turn-on threshold Supply current during UVLO and fault mode typ. max. SO-19 10V – – 14V 17.5V – 110µA 170µA Operating frequency of inverter during RUN mode 20kHz – 120kHz Operating frequency of inverter during preheating mode FRFRUN – 150kHz Preheating time 0ms – 2500ms Adjustable self-adapting dead time max between LS and HS gate drive 2.25µs 2.50µs 2.75µs Adjustable self-adapting dead time min between LS and HS gate drive 1.00µs 1.25µs 1.50µs Operating voltage range of floating HS gate drive -900V – +900V LS current limitation threshold: Ignition/start up/soft start/pre run 1.5V 1.6V 1.7V LS current protection threshold during RUN mode and preheating 0.75V 0.80V 0.85V End-of-life detection threshold -40µA – +40µA Detection of –n-ZVS operation CapMode 1 & 2 – – – PFC preconverter control with critical and discontinuous CM – – – 18µs 22.7µs 26µs Hysteresis of zero current detector – 1.0V – PFC current limitation threshold – 1.0V – 2.47V 2.5V 2.53V Maximum controlled on-time Reference voltage for control of bus voltage Overvoltage detection threshold 2.68V 2.73V 2.78V Undervoltage detection threshold 1.835V 1.88V 1.915V Open loop detection 0.237V 0.31V 0.387V Junction operating temperature range -25°C – +125°C – – – Pb-free lead plating RoHS compliant Power ICs Short Form Data Package 141 Ballast Control ICs Ballast Control ICs ICB2FL01G Features Benefits Able to handle lamp chokes with higher Optimized lamp choke size and reduced BOM costs saturation behavior Special in-circuit test mode for faster test time Excellent dynamic PFC performance enables very low THD across wide load ranges Separate adjustable levels of lamp overload and rectifier effect detection Adjustment of the preheat time No high voltage capacitor required for detection of lamp removal (capacitive mode operation) Automatically restarts by surge and inverter overcurrent events Skipped preheating when line interruption < 500ms Self adapting dead time adjustment of the half bridge driver One single restart at fault mode Dramatically reduced time for key tests such as end of life detection, preheat/ignition timeout and pre-run operation modes Suitable for dimming and multi-power ballasts Enables ballast compatibility with a wider range of lamp types Flexible support of both current and voltage mode preheating Reduced BOM costs Intelligent discrimination between surge & half bridge overcurrent events Meets standards for emergency lighting (according to DIN VDE 0108) Eases design of multi-power ballasts and reduces EMI Enhanced reliability of ballasts ICB2FL02G The ICB2FL02G is functionality identical to the ICB2FL01G with adjustments to certain timings and parameters to further optimize performance in dimming ballasts. Function ICB2FL02G ICB2FL01G Cap load 1 protection Deactivated Activated Suitable for dimming Optimized ü Max. adjustable run frequency 140kHz 120kHz Adjustable dead time 1.05µs 1.05µs to 2.5µs Dead time detector level -50mV -100mV Capacitive mode 2 detector level 3 -50mV -100mV ICB2FL03G Infineon’s latest Ballast Controller ICB2FL03G in SO-16 offers very similar performance and feature set compared to the well established SO-19 product ICB2FL01G. Package 142 ICB2FL03G ICB1FL01G SO-16 small body SO-19 wide body Driver capability 650V 900V Lamp connection Single and series Single, series and parallel LED Driver ICs LED Driver ICs for General Lighting LED based Lighting sources are the best suited candidates to replace inefficient Lighting solutions such as incandescent or halogen lamps that are still widely used today. Current LED driver design and system cost are still a challenge to gain major consumer acceptance. Infineon offers benchmark solutions and represents an outstanding choice to overcome this hurdle. ICL8001G / ICL8002G These devices are designed for off-line LED Lighting applications with high efficiency requirements such as replacement lamps (40/60/100W), LED tubes, luminaires and downlights. Infineon provides a single stage flyback solution with PFC functionality. Innovative primary control techniques combined with accurate PWM generation for phase cut dimming enable solutions with significant reduced component count on a single sided driver PCB for smallest form factor. Benefits ICL8001G simplifies LED driver implementation ICL8002G is optimized for best dimming performance ICL8002G LED- VLED 35V/300mA VIN Detection LED+ Passive Damper Passive Bleeder EE13 (SP_NEW) ICL8001G Power ICs Features Primary side flyback or buck control with integrated PFC and phase angle dimming Optimized for trailing- and leading-edge dimmers Integrated HV startup cell for short time to light Best-in-Class BOM for dimmable LED bulbs High and stable efficiency over wide dimming range –– Good line regulation capabilities based on digital foldback correction –– Low external part count for simplified designs and short-time to market –– Cycle-by-cycle peak current limitation Built-in digital soft-start Auto restart mode for short circuit protection Adjustable latch-off mode for output overvoltage protection + L VIN 90~132V AC VR ZCV VCC ICL 8001G Continuous Mode DIM Control PFC N.C. PWM-Control Protection Gate Driver GND HV Start-Up Cell BSS225 - U1 5 N 6 7 8 GD DRV HV CS N.C. VCC GND ICL8002G VR ZCV 4 3 IPD60R2K0C6 2 1 CS Active Bleeder 143 LED Driver ICs Linear Current Regulators BCR401W / BCR402W / BCR401U / BCR402U / BCR405U / BCR205W The BCR40x family is the smallest size and lowest cost series of LED drivers. These products are perfectly suited for driving low power LEDs in general lighting applications. Thanks to AEC-Q101 qualification, it may also be used in Automotive applications such as brake lights or interior. The advantage versus resistor biasing is: Long lifetime of LEDs due to constant current in each LED string Homogenous LED light output independent of LED forward voltage binning, temperature increase & supply voltage variations See Application Note AN182 for details on replacing resistors The advantage versus discrete semiconductors is: Reduced part count and assembly effort Pretested output current Defined negative temperature co-efficient protection Features and benefits Output current from 10mA to 65mA (adjustable by external resistor) Supply voltage up to 24V (BCR401W, BCR402W) and up to 40V (BCR401U, BCR402U, BCR405U) Reduction of output current at high temperature, contributing to long lifetime LED systems Ease-of-use Very small form factor packages with up to 750mW max. power handling capability Low-Power LED Driver ICs (5–65mA) Product Type Group Topology Vs (min) [V] Vs (max) [V] Iout (typ) [mA] Iout (max) [mA] BCR205W LED controller BCR401U LED drivers for low-power LEDs BCR401W Dimming Package Ptot (max) [mW] Linear 1.8 Linear 1.4 + VfLED 18 0.5 40 10.0 ext. Switch no SOT343 100 65 Digital SC74 LED drivers for low-power LEDs Linear 1.2 + VfLED 18 750 10.0 60 Digital SOT343 BCR402U LED drivers for low-power LEDs Linear 1.4 + VfLED 500 40 20.0 65 Digital SC74 BCR402W LED drivers for low-power LEDs Linear 750 1.4 + VfLED 18 20.0 60 Digital SOT343 500 BCR405U LED drivers for low-power LEDs Linear 1.4 + VfLED 40 50.0 65 Digital SC74 750 Supply voltage 12 VDC LED driver BCR 401/402 Control circuit Rint Sense Control ON/OFF 144 LEDs RSENSE (optional) LED Driver ICs BCR420U / BCR321U / BCR420U / BCR421U / BCR450 The BCR32x and BCR42x LED drivers are dedicated linear regulators for 0.5W LEDs with a maximum output current of 250mA. They are optimized in terms of cost, size and feature set for medium power LEDs in general Lighting applications. Thanks to AEC-Q101 qualification, it may also be used in Automotive applications such as brake lights or interior. Features and Benefits Output current from 10mA up to 300mA for BCR32x (200mA for BCR42xU), adjustable by external resistor Supply voltage up to 40V for BCR42x (24V for BCR32x) Direct Microcontroller interface for PWM dimming with BCR321U/BCR421U Reduction of output current at high temperature, contributing to long lifetime LED systems Ease-of-use Very small form factor packages with up to 1.000mW max. power handling capability Medium- & High-Power LED Driver ICs (65–500mA) Product Type Group BCR320U LED drivers for mid-power LEDs Topology Linear Vs (min) [V] Vs (max) [V] Iout (typ) [mA] Iout (max) [mA] Dimming Package Ptot (max) [mW] 1.4 + VfLED 24 + VfLED 250 300 No SC74 1 1 BCR321U LED drivers for mid-power LEDs Linear 1.4 + VfLED 24 + VfLED 250 300 Digital SC74 BCR420U LED drivers for mid-power LEDs Linear 1.4 + VfLED 40 + VfLED 150 200 No SC74 1 BCR421U LED drivers for mid-power LEDs Linear 1.4 + VfLED 40 + VfLED 150 200 Digital SC74 1 BCR450 LED controller Linear 3.0 27 70 ext. switch Digital SC74 500 VS Power ICs + – RSENSE (optional) Von: BCR 320 BCR 420 Von: µC BCR 321 BCR 421 145 LED Driver ICs DC/DC Switch Mode LED Driver ICs ILD1151 / ILD4001 / ILD4035 / ILD4120 / ILD4180 / ILD6070 / ILD6150 The ILD series are switch mode LED driver ICs for high power LEDs. They combine protection features that contribute to the lifetime of LEDs with the flexibility in output current range from 150mA up to multiple amperes. The new ILD series include LED driver ICs with integrated power stage as well as with external MOSFET achieving up to 98% driver efficiency across a wide range of general Lighting applications. ILD4120, ILD4180, ILD6070 and ILD6150 are buck LED regulators. ILD4001 is a buck LED controller and ILD1151 is a multi-topology LED controller. Features and Benefits Wide input voltage range Scalability in output current from 150mA up to multiple amperes Alternative dimming concepts: digital or analog Vs (min) 146 Vs (max) Iout (typ) Iout (max) Package Over voltage and over current protection Smart thermal protection for ILD2035, ILD4035, ILD4120, ILD6070 and ILD6150 contributing to longer LED lifetime ILD1151 supports boost, buck-boost and SEPIC topologies Dimming Topology fsw Features ILD1151 4.5V 45V 90.0mA 3.000mA SSOP-14 Analog/digital Boost, buckboost SEPIC Adjustable 100-500kHz Multi topology controller, constant current or constant voltage mode, over-voltage, over-current, short on GND protection ILD4001 4.5V 42V 10.0mA 3.000mA DSO-8-27 Analog/digital Hysteretic buck < 500kHz Zhermal protection ILD4035 4.5V 40V 350mA 400mA SC74 Analog/digital Hysteretic buck < 500kHz Smart thermal protection, over-voltage, over-current protection ILD4120 4.5V 40V 1.200mA 1.200mA DSO-8-27 Analog/digital Hysteretic buck < 500kHz Smart thermal protection, over-voltage, over-current protection ILD4180 4.75V 45V 1.800mA 1.800mA DSO-8-27 Digital ILD6070 4.5V 60V 700mA 700mA DSO-8-27 Analog/digital Hysteretic buck ILD6150 4.5V 60V 1.500mA 1.500mA DSO-8-27 Analog/digital Hysteretic buck Fixed frequency 370kHz buck <1000kHz Over voltage, over-current protection, constant current or constant voltage mode Integrated switch rated up to 700mA, PWM or analog dimming, adjustable over temperature protection, over-current protection Integrated switch rated up to 1.500mA, PWM or analog dimming, adjustable over temperature protection, over-current protection LED Driver ICs Support Expert Support for LED Driver ICs Easy Access and High Quality Application Notes, Datasheets & More www.infineon.com/led.appnotes www.infineon.com/led.documents www.infineon.com/lowcostleddriver www.infineon.com/ledoffline LED Driver Online Design Tool www.infineon.com/lightdesk LED Driver Evaluation Boards www.infineon.com/led.evalboards Datasheets 147 Digital I/O ICs ISOFACE™ Galvanic Isolated High Side Switches and Input ICs Our ISOFACE™ product family provides robust and intelligent galvanic isolation for industrial control applications such as Programmable Logic Controllers, Sensor Input Modules, Control Panels and General Control Equipment. The output switches are compact in design, enabling robust and reliable operation at low system cost. Ideal for high speed applications, input ICs are equally robust, reliable and compact – also offering superior EMI robustness and diagnostics. Isolated Output Switches Key Features Integrated galvanic isolation (500V) 8 channels (0.6 or 1.2A, each) Inductive load switching Diagnostic feedback (over-temperature, over-load) Serial and parallel MCU interface Key Benefits Robust and reliable Compact system solution Lower system cost System status feedback Directly interfacing with all MPUs and MCUs Typical Block Diagram Isolated Output Switch Vbb VCC VCC Vbb VCC DIS Control Unit WR Parallel or D0 Serial Interface Transmission Transmission CS µC i.e. XMC1xxx XMC4xxx OUT0 Control & Protection Unit OUT1 Logic DIAG D7 DIAG OUT7 GNDCC GND Switch µC Interface Safety Features Diagnostics Feedback GNDbb Product Overview ISO1H801G ISO1H811G ISO1H812G ISO1H815G Vbb operational range: 11V to 35V ü ü ü ü ü 0.6A 0.6A 0.6A 1.2A 1.2A Load current increase by using outputs in parallel ü ü ü ü ü Inductive clamping energy per channel: 1Joule ü ü ü ü ü parallel parallel serial parallel serial Nominal voltages 5V 3.3V / 5V 3.3V / 5V 3.3V / 5V 3.3V / 5V Isolation voltage: VISO = 500V, UL508 & EN 61131-2 certified ü ü ü ü ü Active current limitation ü ü ü ü ü Thermal shut-down ü ü ü ü ü Common output disable pin ü ü ü ü ü ü ü ü ü ü Max. continuous load current per channel Type Over-temperature Vbb under-voltage Package DSO-36 (16 x 14mm) Infineon Ordering Code 148 ISO1H81xG ISO1H816G ü ü ü ü ü ü ü ü SP000722122 SP000413798 SP000413800 SP000555576 SP000555578 Digital I/O ICs Isolated Digital Input ICs Key Features Integrated galvanic isolation (500V) 8 channels (IEC Type 1/2/3) Up to 500kHz sampling speed Programmable input filters Channel-specific diagnostics (wire-break, undervoltage) Key Benefits Robust and reliable Compact system solution High-speed applications Superior EMI robustness System status feedback Valuable maintenance support Typical Block Diagram Digital Input Switch SW1 SW2 VBB 330nF Serialize 8 Sensors 12kΩ I0H I0L 2kΩ IN7 12kΩ GNDFI I7H I7L GNDBB ISO1I813T ERR Digital Filter Sync CS Logic 2kΩ IN0 DC ENA Deserialize VFI VCC TS WB Parallel or Serial Interface Digital Filter µC e.g. XE166 GND Product Overview Input Characteristics µC Interface Safety Features ISO1I811T ISO1I813T IEC Type: I, II, III ü ü Input status LED ü ü Max sampling frequency 125kHz 500kHz Deglitching filter setting Hard wired Software, individual per channel Synchronous data acquisition – ü 3.3V/5V ü ü Serial & parallel ü ü 500V Isolation voltage ü ü Wire break, channel-specific – ü Vbb undervoltage – ü ü Support for external Vbb supply – Package TSSOP-48 (8 x 12.5mm) ü ü Infineon ordering code SP000876494 SP000876504 Power ICs ISOFACE ™ Reference Design with Microcontroller XMC The EMI-tested reference design is a complete and proven template for product design and shortens development time: Layout proposal which meets IEC 61131-2 (Zone C) requirements Optimized bill-of-materials Example firmware Ordering code: SP0012831904 (available as of April 2015) www.infineon.com/isoface 149 EiceDRIVER™ EiceDRIVER™ High Voltage Gate Driver ICs 1ED020I12-B2 ED- 1ED020I12-BT Enhanced Enhanced Single channel isolated gate driver Single channel isolated gate driver Basic isolation according to EN60747-5-2, Same functions and features as 1ED020I12-B2 recognized under UL1577 Fully functional at transient +/- 1420V and static voltages of +/-1200V High voltage side status feedback 2A sink and source rail-to-rail output Max. Tj = 150°C Package SO-16 300mil Protection functions: –– Enhanced desaturation detection –– Active Miller clamp –– Under-voltage lockout –– Shut down –– Watchdog timer Evaluation board available EVAL-1ED020I12-B2 Basic isolation according to EN60747-5-2, recognized under UL1577 Adjustable two level turn-off function Desaturation detection with 500µA Evaluation board available EVAL-1ED020I12-BT 1ED020I12-FT 1ED020I12-F2 Enhanced Single channel isolated gate driver Same functions and features as 1ED020I12-B2 Functional isolation of 1200V Can be used with evaluation board EVAL-1ED020I12-B2 Typical Application 1ED020I12-F2 +5V RDY DESAT /FLT To control logic CVCC2 GATE VCC GND ININ+ RDESAT CDESAT RST +5V +15V CVCC2 GND2 VEE2 CLAMP 1ED020I12-F2 Enhanced ED- Enhanced Dual channel isolated gate driver Same functions and features as two times 1ED020I12-F2 Package SO-36 300mil Evaluation board available EVAL-2ED020I12-F2 ED- VCC2 ED- Single channel isolated gate driver Same functions and features as 1ED020I12-BT Functional isolation of 1200V Can be used with evaluation board EVAL-1ED020I12-BT 2ED020I12-F2 150 ED- DProt DDESAT RG EiceDRIVER™ 1EDI30J12CP ED- Enhanced Infineon has developed the Direct Drive JFET Topology to enable normally-on SiC JFETs to be driven at best possible efficiency and as safe as normally-off switches. This isolated EiceDRIVER™ dedicated for normally-on SiC JFETs comes with special features and benefits: Single channel driver IC with Coreless Transformer (CT) technology Galvanic isolation, +/- 1200V UVLO 16-17V, optimized for Infineon’s SiC JFET discretes and power modules Bootstrap mode (UVLO 8-9V, logic, MOS driver capability, indicator output) Typical Application 1EDI30J12CP supply failures Minimum 3A rail-to-rail output Extremely low propagation delay of typ. 80ns Green package DSO-19-4 (300mil) Drain cascode VCC1 SiC JFET +5V to SGND Safe turn-off during start up and power JFDrv CVCC SGND Controller MDrv IN VReg EN CLJFG CVReg LV MOSFET VCC2 GND1 CVEE2 VEE2 -25V to VCC2 BSEN Source cascode Power ICs 1EDI30J12CP CoolSiC™ 1200V JFET Portfolio and Recommended Driver / LV MOS for Direct Drive Topology RDS(on) Sales name JFET Package Driver Driver Package LV MOS LV MOS Package Voltage 1200 1200 70 IJW120R070T1 TO-247 1EDI30J12CP DSO-19-4 BSC030P03NS3 G SuperSO8 100 IJW120R100T1 TO-247 1EDI30J12CP DSO-19-4 BSC030P03NS3 G SuperSO8 70 IJC120R070T1 Bare die 1EDI30J12CP DSO-19-4 IPC099P03N Bare die 100 IJC120R100T1 Bare die 1EDI30J12CP DSO-19-4 IPC099P03N Bare die 151 EiceDRIVER™ 2ED020I12-FI ED- 2EDL Compact Family Enhanced 1200V isolated high side half bridge gate driver Galvanic isolation of high side driver 2A sink current, 1A source current Fully functional at transient and static voltages of +/-1200V Integrated operational amplifier and comparator Matched delay times of high side and low side Max. Tj = 150°C Package SO-18 300mil Protection function: –– Hardware input interlocking –– Undervoltage lockout –– Shut down function 2ED020I06-FI 650V isolated high side half bridge gate driver 2A sink current, 1A source current Fully functional at transient and static voltages of +/-650V Matched delay times of high side and low side Max. Tj = 150°C Package SO-18 300mil Protection function: –– Hardware input interlocking –– Under voltage lockout VCC DC-Bus VDD +5V µC 2EDL05I06PF PWM_H HIN PWM_L LIN GND GND VB HO VS LO To Load To Op-amp/ Comparator DC-Bus 152 Compact 600V levelshift high side half bridge gate driver Ultra fast integrated bootstrap diode SO8 and SO14 package Enable function (2EDL23x only) Fault indication (2EDL23x only) Versions with and without interlock Protection functions: –– Asymmetric undervoltage lockout –– Active shut down –– Undervoltage lockout levels for MOSFET and IGBT –– Over-current protection (2EDL23x only) –– Fixed HW dead time optional Evaluation boards available: –– EVAL-2EDL05I06PF –– EVAL-2EDL23I06PJ –– EVAL-2EDL23N06PJ Galvanic isolation of high side driver Typical Application 2EDL05I06PF ED- EiceDRIVER™ ED- Compact Single channel isolated gate driver Fully functional at static voltages of +/- 1200V High CMTI rating dv/dt = 100V/ns Up to 6A min. output peak current Separated source/sink output or single output with Active Miller clamp Short propagation delay of 100ns or 240ns input filter time for Noise Suppression Compact SO-8 150mil package Evaluation board available EVAL-1EDI60I12AF Typical Application 1EDI60N12AF VCC1 C1 VCC2 VCC2 C2 Rg_on 1EDI60N12AF SGND OUT+ GND1 IN IN + OUT- IN - GND2 Rg_off Typical Application 1EDI30I12MF VCC1 VCC1 C1 SGND IN 6EDL Compact Family VCC1 VCC2 1EDI30I12MF OUT GND1 IN + CLAMP IN - GND2 VCC2 C2 Rg ED- Compact 200V and 600V 3-phase gate driver Ultra fast integrated bootstrap diode Fully functional at neg. transient voltages down to -50V (500ns) Programmable restart after over current protection Typical Application 6EDL04I06PT DC-Bus VCC HIN1,2,3 LIN1,2,3 FAULT EN VCC HIN1,2,3 LIN1,2,3 FAULT EN Shut down of all outputs in case of UVLO, OCP Package SO-28 300mil (600V) and package TSSOP-28 (200V) Protection functions: –– Over-current protection (OCP) –– Hardware input interlocking –– Undervoltage lockout (UVLO) –– Fixed hardware deadtime of high side and low side –– Enable function –– Pin compatible variants of first generation available Evaluation boards available: EVAL-6EDL04I06PT EVAL-6EDL04N02PR RRCIN CRCIN VSS VB1,2,3 HO1,2,3 VS1,2,3 To Load Power ICs 1EDI Compact Family LO1,2,3 RCIN COM ITRIP VSS 6EDL04I06PT R Sh 153 EiceDRIVER™ Product Table High Voltage Gate Driver ICs Product Type Products ED- Compact ED- Enhanced * Certified according to DIN EN 60747-5-2 154 Package Topology Voltage Class Source/Sink Current Io+/- Turn-On Propagation Delay (max) 1EDI05I12AF PG-DSO-8 Single 1200V 0.5 / -0.5A 330ns 1EDI10I12MF PG-DSO-8 Single 1200V 1.0 / -1.0A 330ns 1EDI20I12AF PG-DSO-8 Single 1200V 2.0 / -2.0A 330ns 1EDI20N12AF PG-DSO-8 Single 1200V 2.0 / -2.0A 115ns 1EDI20I12MF PG-DSO-8 Single 1200V 2.0 / -2.0A 330ns 1EDI30I12MF PG-DSO-8 Single 1200V 3.0 / -3.0A 330ns 1EDI40I12AF PG-DSO-8 Single 1200V 4.0 / -4.0A 330ns 1EDI60I12AF PG-DSO-8 Single 1200V 6.0 / -6.0A 330ns 1EDI60N12AF PG-DSO-8 Single 1200V 6.0 / -6.0A 115ns 2EDL05I06BF PG-DSO-8 Half Bridge 600V 0.25 / -0.5A 600.0ns 2EDL05I06PF PG-DSO-8 Half Bridge 600V 0.25 / -0.5A 600.0ns 2EDL05I06PJ PG-DSO-14 Half Bridge 600V 0.25 / -0.5A 600.0ns 2EDL05N06PF PG-DSO-8 Half Bridge 600V 0.25 / -0.5A 450.0ns 2EDL05N06PJ PG-DSO-14 Half Bridge 600V 0.25 / -0.5A 450.0ns 2EDL23I06PJ PG-DSO-14 Half Bridge 600V 1.5 / -2.3A 600.0ns 2EDL23N06PJ PG-DSO-14 Half Bridge 600V 1.5 / -2.3A 450.0ns 6ED003L02-F2 PG-TSSOP-28 3-Phase 200V 180 / -380mA 800.0ns 6ED003L06-F2 PG-DSO-28 3-Phase 600V 180 / -380mA 800.0ns 6EDL04I06NT PG-DSO-28 3-Phase 600V 180 / -380mA 800.0ns 6EDL04I06PT PG-DSO-28 3-Phase 600V 180 / -380mA 800.0ns 6EDL04N02PR PG-TSSOP-28 3-Phase 200V 180 / -380mA 800.0ns 6EDL04N06PT PG-DSO-28 3-Phase 600V 180 / -380mA 800.0ns 1ED020I12-B2 PG-DSO-16 Single 1200V 2.0 / -2.0A 195.0ns 1ED020I12-BT PG-DSO-16 Single 1200V 2.0 / -2.0A 2,000.0ns 1ED020I12-F2 PG-DSO-16 Single 1200V 2.0 / -2.0A 195.0ns 1ED020I12-FT PG-DSO-16 Single 1200V 2.0 / -2.0A 2,000.0ns 2ED020I06-FI PG-DSO-18 Half Bridge 650V 1.0 / -2.0A 105.0ns 2ED020I12-F2 PG-DSO-36 Dual 1200V 2.0 / -2.0A 195.0ns 2ED020I12-FI PG-DSO-18 Half Bridge 1200V 1.0 / -2.0A 105.0ns Tj (max) Safety Isolation Type* UVLO ON,max Fault Reporting Shutdown / Enable Input Logic Type Interlock Two Level Turn-Off 150.0 °C – 12.7V – – pos/neg – – 150.0 °C – 12.7V – – pos/neg – – 150.0 °C – 12.7V – – pos/neg – – 150.0 °C – 10.0V – – pos/neg – – 150.0 °C – 12.7V – – pos/neg – – 150.0 °C – 12.7V – – pos/neg – – 150.0 °C – 12.7V – – pos/neg – – 150.0 °C – 12.7V – – pos/neg – – 150.0 °C – 10.0V – – pos/neg – – 150.0 °C – 12.4V – EN pos – – 150.0 °C – 12.4V – EN pos ü – 150.0 °C – 12.4V – EN pos ü – 150.0 °C – 9.9V – EN pos ü – 150.0 °C - 9.9V - - pos ü no 150.0 °C – 12.4V OCP EN pos ü – 150.0 °C – 9.9V OCP EN pos ü – 125.0 °C – 12.5V ITRIP EN neg ü – 125.0 °C – 12.5V ITRIP EN neg ü – 125.0 °C – 12.5V ITRIP EN neg ü – 125.0 °C – 12.5V ITRIP EN pos ü – 125.0 °C – 9.8V ITRIP EN pos ü – 125.0 °C – 9.8V ITRIP EN pos ü – 150.0 °C Basic 12.6V DESAT /RST pos/neg – – 150.0 °C Basic 12.6V DESAT /RST pos/neg – ü 150.0 °C – 12.6V DESAT /RST pos/neg – – 150.0 °C – 12.6V DESAT /RST pos/neg – ü 150.0 °C – 13.5V – /SD pos ü – 150.0 °C – 12.6V DESAT /RST pos/neg – – 150.0 °C – 13.5V OCP /SD pos ü – Power ICs EiceDRIVER™ Product Table 155 EiceDRIVER™ Nomenclature Naming System EiceDRIVER™ (Driver Boards and Existing Gate Driver) 2ED 020 I 12 -F 2 Additional Function or Revision I = Interlock A = Automotive Channel 1 = 1 Channel EiceDRIVER™ 2 = 2 Channel / half bridge EiceDRIVER™ 6 = 6 Channel (3Phase) EiceDRIVER™ Isolation Class F = Functional B = Basic Output Current Rating *100mA Voltage Class *100V Isolation Technology I = SPT5/B6CA CLT L = SOI N = No EiceDRIVER™ (Gate Driver ICs Since 2012) 1ED Channel 1 = 1 Channel EiceDRIVER™ 2 = 2 Channel / half bridge EiceDRIVER™ 6 = 6 Channel (3Phase) EiceDRIVER™ Isolation Technology S = SafeCLT B = BasicCLT I = CLT L = SOI-LS Output Current Rating *100mA 156 I 60 I 12 A F Package Special Function Voltage Class *100V Switch Type Optimization J = JFET 16-20V I = IGBT 11-13V N = MOS 8-10V EiceDRIVER™ Support Expert Support for EiceDRIVER™ Easy Access and High Quality Application Notes, Datasheets & More www.infineon.com/eicedriver www.infineon.com/eicedriver-enhanced www.infineon.com/eicedriver-compact EiceDRIVER™ Boards www.infineon.com/eicedriver-safe Datasheets 157 CAN/LIN Transceivers CAN/LIN Transceivers Proven Quality for Power Management Applications Our CAN transceivers provide proven quality, reliable track records and high robustness in automation applications. Features include excellent electromagnetic performance and low levels of electromagnetic interference (EMI). They are also designed for ISO compliance. While our IFX1050G, IFX1050 GVIO and IFX1040SJ devices are optimized for high-speed communication, the IFX1054G variant is suited for fault tolerance at lower data rates, where a separate flag supports diagnostics. Key Features Key Benefits Transmission rates up to 1Mbit/s Low current consumption ISO 11898 compliance Excellent EMC performance and EMI robustness Low-power modes Pin-to-pin replacements for industry-standard parts Support of failure conditions Bus wake-up feature Receive-only mode Standby/sleep mode Thermal protection Block Diagram IFX1050 GVIO IFX1050 GVIO 3 5 CANH CANL 7 6 Output Stage Driver 1 Temperature Protection = Mode Control Receiver GND 158 2 8 4 VCC V33 TxD INH RxD CAN/LIN Transceivers Product Portfolio Product Type Transceiver Type Transm. Rate (Max) Quiescent Current Bus Wake-Up Capability Wake-Up Inputs Package High-speed CAN, ISO11898-2 1MBaud <10µA @ 5V standby No No PG-DSO-8 IFX1050GVIO High-speed CAN, ISO11898-2 1MBaud <10µA @ 5V standby No No PG-DSO-8 IFX1040SJ High-speed CAN, ISO11898-2, ISO11898-5 1MBaud <10µA @ 5V standby Yes Yes, STB PG-DSO-8 IFX1054G Fault tolerant CAN, ISO11898-3 125kBaud <65µA sleep mode Yes Bus wake-up and wake-up pin PG-DSO-14 IFX1021 LIN 1.3, 2.0,2.1 20kBaud <10µA sleep mode Yes Bus wake-up and wake-up pin PG-DSO-8 Power ICs IFX1050G www.infineon.com/industrialtransceivers 159 Voltage Regulators Voltage Regulators Energy-Efficient Voltage Regulators and Trackers Our linear voltage regulators and trackers help to reduce energy consumption, extending operating time and minimizing operating costs across all kinds of systems. The wide supply voltage range, low quiescent current, rich protective feature set and choice of packages make our devices the perfect fit across a broad application spectrum, even beyond typical Automation designs. Our trackers are ideal as additional supplies for off-board loads to increase system reliability. Key Features Input voltage up to 60V Output current up to 1.5A Output voltage adjustable or fixed to specific values Quiescent current down to 20µA Overload, overtemperature, short-circuit and reverse-polarity protection Low current consumption Extended temperature range -40°C ... +125°C Key Benefits Pin-to-pin compatibility with industry-standard parts Very low dropout voltage Trackers for optimized heat distribution and external protection Trackers for maximum system cost reduction Small robust packages Infineon Microcontroller Families and Industrial Voltage Regulators Microcontroller Family Input Voltage [V] Input Current (max.) [mA] Voltage Regulator XMC1000 Family 1.8 … 5.5 <100 IFX54211/IFX2931/IFX4949/IFX25001/IFX544xx XMC4000 Family 3.3 <500/300 IFX1763/IFX544xx/IFX1117 XC8xx 3.3 … 5.0 200 IFX20001/IFX24401/IFX2931/IFX21401/IFX4949/ IFX544xx XE166/XC2000 1.5 and 3.3 or 5.0 100 IFX25401/IFX24401/IFX2931/IFX4949 TriCore™ 1.5 … 3.3 >400 IFX27001/IFX8117/IFX91041/IFX80471/IFX25001/ IFX1117 Industrial Linear Voltage Regulator (Selection Tree) 20V >20 … 60V Maximum Input Voltage Output Current Output Current ≤500mA IFX54441EJV Adj, 3.3V, 5V >500mA 1 <500mA IFX20001 3.3V, 5V 300mA 800mA 30mA 150mA EN, Rev. Pol, 2% 2% Accuracy EN, Rev. Pol, 4% EN IFX1963 Adj IFX20002 3.3V, 5V IFX24401 5V IFX1763 Adj, 3.3V, 5V 2 IFX54211 3.3V 500mA 1500mA 30mA 300mA EN, Rev. Pol, 2.5% EN, Rev. Pol, 1.5% EN, Rev. Pol, 4% EN, 2% IFX21401 50mA 4 IFX21004 60V Low Quiescent Current IFX4949 IFX25001 2.5V, 3.3V, 5V 2 Low Noise Behavior 100mA 3 Small Package 1 4 Tracker! High Accuracy 5 Ultra Low Quiescent Current 6 Dual Output 7 Very Low Dropout RST, 1% IFX2931 3.3V, 5V 100mA www.infineon.com/powersupply 3 IFX78M05 500mA 35V, 4% 5 35V, 4% 6 400mA 400mA EN, Rev. Pol, 2% IFX27001 Adj, 1.5V, 1.8V, 2.6V, 3.3V, 5V 1000mA 6 45V, Rev. Pol, 4% IFX25401 Adj, 5V IFX7805 5V 1000mA 30/150mA 0.5% Output Current 160 ≥500mA 3 IFX1117 Adj, 3.3V 7 40V, 3% High-Side Switches PROFET™ High-Side Switches Protected High-Side Switches Our PROFET™ high-side switches sit between the supply and load in order to control the application. These high-side switches deliver a broad range of smart features, including various protective and diagnostic functions. Since PROFET™ devices can manage all kinds of resistive, capacitive and inductive loads, they can be used across a huge variety of industrial applications. Key Features RoHS compliance Very low stand-by current ESD protection, optimized EMC PWM capability Key Benefits Complete, built-in protection Flexible design for all kinds of resistive, capacitive and inductive loads Very low power DMOS leakage current in OFF 3.3V and 5V compatible logic inputs Protection features: load dump, current limitation, thermal shutdown, loss of ground/battery protection, stable behavior at undervoltage, overvoltage, reverse polarity Diagnostic features: open-load in on- and off-state, short-circuit to battery and ground, overtemperature sense Diagnosis: digital or as proportional load current sense Load Current Sense Internal Power Supply IN SP SEN or CLA GND Vbb Gate Control & Charge Pump Logic Open Load Detection ESD Protection Clamp for Inductive Load Power ICs Block Diagram Multi Step Load Current Limitation OUT Temperature Sensor RGND 161 High-Side Switches Product Portfolio Product Type Number of Channels ITS4060S-SJ-N 1 ITS4100S-SJ-N RDS(on) (typ) EAS [mΩ] Nominal Load Current [A] IL(SC) (typ) [mJ] Recommended Operating Voltage Range [V] Diagnosis N/A, Digital, Current Sense Package 50 3.1 900 @1.5A 5.0 … 34.0 17.0 1 70 2.4 870 @ 1.0A N/A PG-DSO-8 5.0 … 34.0 10.0 N/A PG-DSO-8 ITS4200S-ME-O 1 ITS4141D 1 150 1.1 150 1.1 700 @ 0.5A 11.0 … 45.0 3.0 N/A PG-SOT223-4 12,000 @ 0.5A 11.0 … 45.0 3.0 N/A ITS4200S-SJ-D 1 150 PG-TO-252-5 1.7 125 @ 1.0A 6.0 … 52.0 6.5 Digital PG-DSO-8 ITS4200S-ME-P 1 ITS4200S-ME-N 1 150 2.2 160 @ 1.0A 11.0 … 45.0 3.0 N/A PG-SOT223-4 160 1.2 500 @ 0.5A 5.0 … 35.0 1.5 N/A ISP752T PG-DSO-8 1 200 1.7 125 @ 1.0A 6.0 … 52.0 6.5 N/A PG-DSO-8 ITS4300S-SJ-D 1 250 0.8 800 @ 0.3A 5.0 … 34.0 1.2 Digital PG-DSO-8 ITS41K0S-ME-N 1 1000 0.55 1,000 @ 0.15A 5.0 … 34.0 0.9 N/A PG-SOT223-4 ITS5215L 2 90 2 x 2.0 178 @ 3.5A 5.5 … 40.0 15.0 Digital PG-DSO-12 ITS42K5D-LD-F 2 2500 2 x 0.25 Freewheeling 4.5 …45V 600mA Digital PG-TSON-10 ITS724G 4 90 4 x 2.0 120 @ 3.3A 5.5 … 40.0 15.0 Digital PG-DSO-20 ITS716G 4 140 4 x 1.0 76 @ 2.3A 5.5 … 40.0 9.0 Digital PG-DSO-20 ITS711L1 4 200 4 x 1.0A 150 @ 1.9A 5.0 … 35.0 7.5 Digital PG-DSO-20 ITS42008-SB-D 8 200 8 x 0.6 10,000 @ 625mA 11.0 … 45.0 3.0 Digital PG-DSO-36 [A] Industrial PROFET™ Evaluation Board Plus Samples The industrial PROFET™ universal evaluation kit enables you to test the performance of the industrial PROFET™ product family. The evaluation kit includes the board plus three samples of each of the new single channel products. Suitable for: ITS4060S-SJ-N ITS4100S-SJ-N ITS4200S-SJ-D ITS4300S-SJ-D ITS4200S-ME-N ITS4200S-ME-O ITS4200S-ME-P ITS41K0S-ME-N www.infineon.com/profet 162 DC/DC Converters DC/DC Converters Robust Range of Converters for the Widest Application Spectrum Our high-efficiency switching regulators and controllers help to reduce energy consumption. In addition to extending the operating time of battery-powered systems, they also significantly improve the thermal budget of the application. Overall, this translates into minimal operating costs. For your design flexibility, they are available as adjustable voltage variants as well as with dedicated fixed output voltage values. Key Features Input voltage up to 60V Output currents going from 500mA up to 10A Switching frequencies ranging from 100kHz to 2.2MHz Shutdown quiescent current down to below 2µA Key Benefits High-efficiency regulation Only a few external components needed for stable regulation Perfectly suited for regulation in pre-/post-regulation Power Supply architectures Current limitation and overtemperature protection Enable feature DC/DC Converters VQ (multiple) Output Current Output Current Type [A] Product Features Package IFX81481ELV Adjustable Buck Controller 10.0 10A synchronous DC/DC adjustable Step Down Controller; f = 100 – 700kHz, N PGSSOP-14 IFX90121EL V50 5.0V Buck Converter 0.5 Vin up to 45V, 2.2MHz Step-Down Regulator with low quiescent Current PGSSOP-14 IFX80471SK V Adjustable Buck Converter 2.3 Vin up to 60V; VQ adjustable from 1.25V up to 15V; external MOS PG-DSO-14 IFX80471SK V50 5.0V Buck Converter 2.3 Vin up to 60V; external MOS PG-DSO-14 IFX91041EJV Adjustable Buck Converter 1.8 VQ adjustable from 0.6V up to 16V; tolerance 2% up to 1000mA PG-DSO-8 IFX91041EJ V33 3.3V Buck Converter 1.8 VQ fixed to 3.3V; tolerance 2% up to 1000mA PG-DSO-8 IFX91041EJ V50 5.0V Buck Converter 1.8 VQ fixed to 5.0V; tolerance 2% up to 1000mA PG-DSO-8 Block Diagram IFX91041 Industrial DC/DC Buck Regulators (Selection Tree) VS EN 7 45V Output Current 5 BDS Feed Forward SYNC Buck Converter 1 6 Oscillator 4 Band-gap Reference IFX91041 BUO IFX90121 5V >45 … 60V Output Current ≤1A Charge Pump Overtemperature Shutdown 3 Maximum Input Voltage 8 Enable COMP Power ICs Product Type >1A IF91401 Adj, 5V, 3.3V ≥2A IFX81401 Adj IFX80471 Adj, 5V 500mA 1.8A 10A 2.3A 2.2MHz 370kHz Synchronous controller 60V, 360kHz FB Soft-start Ramp Generator 2 GND www.infineon.com/industrial-dcdc-converters 163 Microcontroller XMC – 32-bit Industrial Microcontrollers One Microcontroller Platform. Countless Solutions. Our XMC 32-bit Microcontroller family gives you a real competitive advantage. This wide and scalable portfolio offers excellent real-time performance. Designed for quality and robustness, it offers configurable and fast peripherals which operate largely autonomously. This means the XMC can be adapted to the specific needs of different target markets such as building and factory automation, power and energy, home and professional computing and transportation. Customers benefit from a wide portfolio and ecosystem powered by an ARM® Cortex™ -M0 (XMC1000 family) and Cortex™ -M4 (XMC4000 family). DAVE™ - Digital Application Virtual Engineer A complete set of development tools, ready-to-use software solutions and supporting services are available for XMC Microcontrollers from Infineon and various third-party tool and software vendors. These tools and software products support the entire development cycle to ensure a highly efficient development process. Infineon’s free and revolutionary Eclipse-based IDE (Integrated Development Environment) enables a simple and straightforward development flow for less risk and effort. This is achieved thanks to an intuitive graphical interface and more than 350 application-optimized, configurable, tested and well documented apps and examples. Use of DAVE™ generated source code with other tools from the wide ARM ecosystem is supported. Key Features Integration of powerful peripherals Real-time and deterministic behavior Operation at up to 125°C ambient temperature 164 Key Benefits Industrial, cross-market Microcontroller suited to widest application spectrum Excellent real-time performance Long-term product availability until 2027 Easy design-in with DAVE™ IDE and DAVE™ Apps – advanced high-level GUI-based application-orientated programming using predefined, configurable and tested software components Microcontroller Infineon XMC 32-bit Microcontrollers Based on ARM® Cortex™ -M Parameter XMC1000 XMC1100 Core XMC1200 DSP instruction set – – System Memory ✓ ✓ up to 80MHz up to 120MHz 1x 2x DMA – Primitive Memory Protection (PAU) Memory Protection Unit (8 Regions) Watchdog ✓ ✓ Real-time clock ✓ ✓ 8ch ✓ 14 / 22 / 26 / 34 / 35 Supply voltage 1.8 to 5.5V 45 / 79 / 123 3.13 to 3.63V -40 ... 85°C / 105°C / 125°C 16 – 200KB 8 – 200KB 64KB 256KB ✓ 16KB – Ext memory interface – SysTick ✓ CCU4 (4 ch) 16KB 20KB – 12-bit ADC up to 12ch, 1xADC (1 MSPS) 12-bit DAC 1MB 40KB 80KB 160KB 1KB 4KB – ✓ ✓ 1x CCU8 (4 ch) 512KB ✓ 16KB Cache Comparator 34 / 49 -40 ... 85°C / 105°C 8 – 64KB Error Correction Code (ECC) RAM 12ch – Number of I/Os Operating temperature Timer 120MHz MPU Flash Analog XMC4500 – up to 64MHz Programmable hardware interconnect matrix XMC4400 ARM® Cortex™ -M4 64MHz Floating Point Unit (FPU) Hibernate domain Communication XMC4200 80MHz – Peripherals speed – 2x 4x 1x 2x up to 9ch, 2 x ADC (2 MSPS) up to 26ch, 4x ADC (2 MSPS) 1x up to 12ch, 2x ADC (1 MSPS) – 2x – Up to 3 x Programmable comparators built into Hi-Res PWM IEEE 1588 ethernet MAC – – 1x RMII & MII USB – FS DEV FS OTG SDIO/SD/MMC – – ✓ 2ch, 1x FIFO (64 word) 4ch, 2 x FIFO (64 word) 6ch, 2 x FIFO (64 word) – 2 nodes, 64 message objects 3 nodes, 64 message objects USIC (UART, SPI, QSPI, I2C, I2S) CAN 2.0 B Application XMC4100 32MHz Math coprocessor Hi-Res PWM (150ps) – ∆∑ Demodulator – 4ch – – 4ch POSIF – – 1x Capacitive touch control – Up to 16ch – Up to 7ch Up to 8ch LED matrix control – Up to 128 LEDs – Up to 28 LEDs Up to 40 LEDs Brightness control unit DAVE™ apps IDEs XMC1300 ARM® Cortex™ -M0 Frequency Other XMC4000 – Packages 2x Up to 9ch – Code library with basic system, peripheral, and advanced application-oriented components for Motor Control, Power Conversion, Lighting, Communication, and many more applications. Debug and trace Ecosystem (IDEs, compiler, debugger) 1x Microcontrollers Infineon XMC MCUs SWD, SPD SWD, JTAG, Trace Infineon DAVE™ (free) and partner ARM®/KEIL™ (free up to 128KB, XMC1000), Atollic, IAR Systems, Rowley Associates, TASKING PG-VQFN-24/40 PG-TSSOP-16/38 PG-VQFN-24/40 PGTSSOP-16/28/38 PG-VQFN-24/40 PG-TSSOP-16/38 PG-VQFN-48 PG-LQFP-64 PG-VQFN-48 PG-LQFP-64 PGLQFP-64/100 PGLQFP-100/144 PG-LFBGA-144 www.infineon.com/xmc www.infineon.com/dave 165 Microcontroller AURIX™ – 32-bit Microcontrollers 32-bit Multi-Core TriCore™ – Safety Joins Performance AURIX™ is Infineon’s family of Microcontrollers serving exactly the needs of Industrial applications in terms of performance and safety. Its innovative multi-core architecture, based on up to three independent 32-bit TriCore™ CPUs @300MHz, has been designed to meet the highest safety standards while increasing the performance at the same time. The key strengths of the scalable AURIX™ family is to combine multiple worlds in one family, supporting safety and security as well as high-performance computing and the latest connectivity as well as innovative Power Supply concepts. Using the AURIX™ platform, developers will be able to implement applications like Motor Control and Drives, PLC, or any other Automation application with the scalable MCU platform. Developments using AURIX™ will require less effort to achieve the SIL/IEC61508 standard based on its innovative safety concept and multiple HW safety features. The integrated hardware security module provides safety and also helps to prevent external interrupts. Furthermore, AURIX™ has enhanced communication capabilities to support communication between CAN, LIN, FlexRay™ and ethernet buses. Key Features TriCore™ with DSP functionality Best-in-Class real-time performance: triple TriCore™ with up to 300MHz per core Supporting floating point and fix point with all cores From single core to multi-core Encapsulation feature allows software development without interference for multiple applications HW accelerators Up to 2.75MB of internal RAM, up to 8MB of flash Innovative single supply 5V or 3.3V External memory interface IEC61508 conformance to support safety requirements up to SIL3 Embedded EEPROM Advanced communication peripherals: CAN, LIN, SPI, FlexRay, ethernet 166 Key Benefits High scalability gives the best cost-performance fit High integration leads to significant cost savings High integration leads to reduced complexity Innovative supply concept leads to Best-in-Class power consumption Microcontroller AURIX™ Family Package Scalability TQFP-80 TQFP-100 LQFP-144 TQFP-144 LQFP-176 9x Series up to 8MB Max. SRAM 2.75MB Triple-Core 7x Series up to 4MB Max. SRAM 472KB Triple-Core 6x Series up to 2.5MB Max. SRAM 752KB Dual-Core TC264 4x Series up to 2MB Max. SRAM 96KB Single-Core up to 2MB Max. SRAM 708KB Lockstep-Core up to 1MB Max. SRAM 96KB Lockstep-Core 1x Series up to 512KB Max. SRAM 56KB Lockstep-Core BGA-416 LFBGA-516 TC297 TC298 TC299 TC275 TC277 TC265 TC267 TC244 3x Series 2x Series LFBGA-292 TC233 TC234 TC222 TC223 TC224 TC212 TC213 TC214 TC237 Upgrade/Downgrade with pin-compatible packages Advanced package technologies deliver the best price/performance ratio Customers can choose between different devices in the same pin-compatible package Microcontrollers n n www.infineon.com/aurix 167 Current Sensors Current Sensors The Miniaturization Advantage TLI4970 is a high-precision current sensor based on our proven Hall technology. Its coreless concept supports the miniaturization trend defining today’s sensor designs. It is a fully digital solution with the added bonus of ease-of-use. There is no need for any external calibration or other parts (such as A/D converters, Op-amps, reference voltage sources), reducing the overall implementation effort, PCB space and cost significantly. TLI4970 provides superior accuracy compared with existing open- or closed-loop systems with magnetic cores. It has additional functionality such as overcurrent detection and programmable filters, while offering a significantly smaller footprint and lower power consumption. Key applications include AC/DC inverters, DC/DC converters and PFC Power Supplies and drives. Key Features Key Benefits AC & DC measurement range up to +/-50A Ideal for Automation applications Highly accurate over temperature range and lifetime Plug and play solution – no external calibration needed (max. 1.0% (0 h), 1.6% (over lifetime) of indicated value) Much smaller footprint than existing solutions Low offset error (max. 75mA over temperature and lifetime) Reduced implementation effort, PCB space and cost High magnetic stray field suppression Small package size and weight for SMD mounting Fast overcurrent detection with configurable threshold Galvanic isolation up to 2.5kV max. rated isolation voltage (UL1577) 16 bit digital SPI output (13 bit current value) Small 7.0 x 7.0mm2 SMD package Block Diagram TLI4970 IP+ Supply, Biasing, Reset, Oscillator, Bandgap VDD GND EEPROM Diff. Hall Galvanic Separation ADC CS T S MUX ADC DSP Digital IF SCLK DOUT DAC IP- www.infineon.com/tli4970 168 FOC Fast Overcurrent Detection (open-drain) Hall Switches Hall-Effect Switches The Energy-Saving Option with Excellent Accuracy and Robustness Our portfolio of Hall switches comprises unipolar and omnipolar switches, bipolar latches and double Hall switches. They are suited to a wide range of applications such as Position Sensing, Index Counting, BLDC motor control, etc. These devices show excellent accuracy and robustness against electrical disturbances and are available in a variety of packages. Key Features Operating supply voltage 3–32V Reverse polarity protection (-18V) Overvoltage capability up to 42V without external resistor Key Benefits Reduction of system power consumption Reduced system size Removal of protection devices Reliable system operation Low current consumption (1.6mA) Increased motor efficiency Active error compensation Broad range of switching thresholds available High ESD performance, up to 7kV HBM for all applications Special industrial versions available Small SMD package SOT23 Leaded package Hall Switch Types Uni-/omnipolar switches Double Hall Speed/Direction Switches N S N S N Rotation Direction S S N B Main application: BLDC motor commutation B Proximity detection S Speed N Direction t Branded Side of IC Absolute position sensing in power operated systems Sensors Latch (bipolar) www.infineon.com/hall-switches 169 Hall Sensors Linear Hall Sensors Highly Accurate Angular and Linear Position Measurement All products of our linear Hall family measure the vertical component of a magnetic field. The output signal is directly proportional to the sensed magnetic field. Building on these principles, our TLE499x family of linear Hall ICs has been designed specifically to meet the requirements of highly accurate angular and linear position measurement. They are also suited to current measurement applications. Key Features Key Benefits Single supply voltage 4.5–5.5V Wear-free operation Temperature range -40 ... +150°C Highly accurate contactless position sensing Linear ratiometric output between -200mT and +200mT In-system calibration Flexible system implementation within three ranges Sensitivity offset and clamping programmable Digital temperature and stress compensation High-voltage capability and reverse polarity protection Low drift of output signal over temperature and lifetime 20-bit digital signal processing Analog and digital interfaces Block Diagram TLE4998 VDD Interface Bias Supply Spinning Hall EEPROM OUT A D Digital Signal Processing Temperature Sense A D ROM www.infineon.com/magnetic-sensors 170 OUT Generation GND Product Solutions Interface iGMR Angle Sensors Compact Designs in Small Outline Packages Our angle sensor family is based on integrated Giant Magneto Resistance (iGMR) technology. These sensors detect the orientation of an applied magnetic field by measuring sine and cosine angle components with monolithically integrated magneto-resistive elements. This allows them to easily determine the absolute orientation of the magnetic field between 0° and 360°. Data processing and communication interfaces are integrated on the same silicon chip as the sensing elements, allowing a compact design using small outline packages. Our angle sensor family offers a broad variety of communication interfaces, as well as different levels of data processing and self-test capabilities. Ideal for functional safety-critical applications, our TLE5309D combines a TLE5009 iGMR with a TLE5109 iAMR chip, whereas the TLE5012BD combines two TLE5012B iGMR in one fully integrated dual-sensor package. Target applications of our iGMR sensors include Contactless Angle Measurement, Rotational Position Measurement, Steering Angle Measurement and BLDC motor commutation. Features Integrated GMR (iGMR) technology 0–360° angle measurement with sine and cosine bridge Supply voltage 3.3 or 5.0V On-chip temperature compensation of amplitude and offset Temperature range -40°C ... +150°C PG-DSO-8 package Sales Name Description Interface Order Code TLE5009 E1000 VDD: 3.3V; static offset compensation Analog SP000912764 TLE5009 E1010 VDD: 3.3V; TCO1) Analog SP000912774 TLE5009 E2000 VDD: 5.0V; static offset compensation Analog SP000912760 TLE5009 E2010 VDD: 5.0V; TCO1) Analog SP000912770 TLE5012B E1000 VDD: 3.3V & 5.0V SPI2), IIF3) SP001166960 TLE5012B E3005 VDD: 3.3V & 5.0V SPI2), HSM4) SP001166964 TLE5012B E5000 VDD: 3.3V & 5.0V SPI2), PWM5) SP001166968 TLE5012B E9000 VDD: 3.3V & 5.0V SPI2), SPC6) SP001166998 TLE5012BD E1200 VDD: 3.3V & 5.0V DualDie SPI2), IIF3) SP001205296 TLE5012BD E9200 VDD: 3.3V & 5.0V DualDie SPI2), SPC6) SP001205300 TLE5309D E1211 VDD: 3.3V (AMR & GMR), TCO1), DualDie Analog SP001191262 TLE5309D E2211 VDD: 5.0V (AMR & GMR), TCO1), DualDie Analog SP001191266 TLE5309D E5201 VDD: 5.0V (AMR) & 3.3V (GMR), DualDie Analog SP001145340 TLE5009 EVALKIT Evaluation kit containing interface box (PGSISI-2) and evaluation board incl. – magnet and software SP000871462 TLE5009 EVALBOARD Evaluation board incl. magnet and software (interface box is not included, but is required for operation) – SP000871466 TLE5012B EVALKIT Evaluation kit containing interface box (PGSISI-2) and Evaluation board incl. – magnet and software SP000912902 TLE5012B EVALBOARD Evaluation board incl. magnet and software (interface box is not included, but is required for operation) SP000912898 1) TCO = Temperature Compensation 2) SPI = Serial Peripheral Interface 3) IIF = Incremental Interface 4) HSM = Hall Switch Mode – Sensors Product Portfolio 5) PWM = Pulse Width Modulation 6) SPC = Short PWM Code 171 iGMR Angle Sensors Benefits TLE5009 Block Diagram TLE5009 The analog sensor output signals can be directly connected to the analog inputs of a Microcontroller The output signals are offset- and temperaturecompensated Output signals can be read as single-ended or differential voltage Signal amplitudes are independent from supply voltage variations VDD COS_P DC-Offset & Fuses Amplifier X-GMR COS_N PMU & Temperature Compensation VGMR SIN_P Amplifier Y-GMR SIN_N GND1 GND2 Benefits TLE5012B Block Diagram TLE5012B Different digital interfaces available (SPI, PWM, HSM, IIF, SPC) Integrated angle calculation based on sine and cosine values Increased accuracy with auto-calibration functionality Prediction of output signal to compensate latency High-speed angle update rate up to 23.4kHz VDD VRG X GMR Y GMR VRA SD-ADC SD-ADC VRD OSC TLE5012B PLL CSQ Digital Signal Processing CCU CORDIC Temp. SD-ADC CLK FUSES SSC Interface SCK DATA Incremental IF PWM HSM SPC IFA IFB GND www.infineon.com/angle-sensors 172 Support Expert Support for ... ... Microcontrollers, Sensors and Power ICs Application Notes, Datasheets & More www.infineon.com/xmc www.infineon.com/dave www.infineon.com/aurix www.infineon.com/industrialtransceivers www.infineon.com/tli4970 www.infineon.com/hall-switches www.infineon.com/magnetic-sensors www.infineon.com/angle-sensors www.infineon.com/industrial-dcdc-converters www.infineon.com/powersupply www.infineon.com/profet Datasheets 173 Package Overview Packages SMD Technology TO-252-2 (DPAK) 2 9.9 x 6.5 x 2.3 DPAK (TO-252) 3 D2PAK 7pin (TO-263 7pin) 7 15.0 x 10.0 x 4.4 19 12.8 x 10.3 x 2.65 5.0 x 6.0 x 1.75 20 12.8 x 10.3 x 2.65 5.15 x 6.15 x 1.0 3.0 x 3.0 x 0.9 9.7 x 6.4 x 1.2 TSON-8 ThinPAK 5x6 8 5.0 x 5.0 x 1.0 5.15 x 6.15 x 1.0 10.0 x 6.0 x 1.75 3 3.0 x 2.8 x 1.1 3.0 x 3.0 x 0.9 28 18.1 x 10.3 x 2.65 5 9.9 x 6.5 x 2.3 14 8.75 x 6.0 x 1.75 3 2.9 x 2.4 x 1.0 8 3.3 x 3.3 x 1.0 SO-16/12 2.9 x 2.5 x 1.1 S3O8 SuperSO8 fused leads 8 5.15 x 6.15 x 1.0 DSO-28 48 15.0 x 10.0 x 4.4 16 10.0 x 6.0 x 1.75 3 4.5 x 4.0 x 1.5 8.0 x 8.0 x 1.0 15.0 x 10.0 x 4.4 18 12.8 x 10.3 x 2.65 SO-18 SOT-223 4 6.5 x 7.0 x 1.6 TISON (power stage 5x6) WISON (power stage 3x3) 8 8 5.0 x 6.0 x 1.0 CanPAK™ S-Size 6 4.8 x 3.8 x 0.65 36 15.9 x 11.0 x 3.5 3.0 x 3.0 x 0.8 CanPAK™ M-Size 7 DSO-36 11.68 x 9.9 x 2.3 48 VQFN-48 UIQFN-32 DrBlade™ 1.0 WIQFN-38 DrBlade™ 2.0 6.0 x 6.0 x 0.9 32 5.0 x 5.0 x 0.6 2 SOT-89 TSSOP-48 12.5 x 6.1 x 1.1 D2PAK 2pin (TO-263-2) SO-16 VSON (ThinPAK) 4 TO-Leadless (TOLL) 8 3 SOT-23 TSOP-6 6 D2PAK (TO-263) SO-14 SC59 TDSON-10-7 10 TSSOP-28 28 2.0 x 2.1 x 0.9 SuperSO8 dual 8 TDSON-10-2 10 12 SOT-363 6 SuperSO8 8 9.7 x 6.6 x 2.34 SO-20 SOT-323 2.0 x 2.1 x 0.9 3 SO-8/SO-8 dual 8 SO-19 3 9.9 x 6.5 x 2.3 Reverse DPAK (Rev. TO-252) DPAK 5pin (TO-252 5pin) 38 6.6 x 4.5 x 0.8 IQFN-40 40 LxWxH pin-Count All Dimensions in mm All products are available in green (RoHS compliant). 174 6.0 x 6.0 x 0.8 UIQFN-19 DrBlade™ 3 19 Package (JEITA-code) X 6.3 x 4.9 x 0.65 5.0 x 4.0 x 0.7 Package Overview THD Technology 3 15.5 x 6.5 x 2.3 IPAK SL (TO-251 SL) 3 TO-220 FullPAK 3 29.6 x 10.5 x 4.7 8 9.52 x 8.9 x 4.37 10.7 x 6.5 x 2.3 I2PAK (TO-262) 3 TO-220-6-46 6 21.7 x 9.9 x 4.4 14 19.5 x 8.9 x 4.37 DIP-8 25.1 x 10 x 4.4 TO-220 real 2pin 2 29.15 x 10.0 x 4.4 3 40.15 x 15.9 x 5.0 TO-220-6-47 6 26.1 x 9.9 x 4.4 20 24.6 x 9.9 x 4.2 DIP-14 DIP-20 TO-220 2pin 2 TO-247 29.1 x 9.9 x 4.4 TO-220 3pin 3 29.15 x 10.0 x 4.4 7 9.52 x 8.9 x 4.37 TO-247 4pin 3 40.15 x 15.9 x 5.0 DIP-7 Package (JEITA-code) X LxWxH pin-Count All Dimensions in mm All products are available in green (RoHS compliant). Packages IPAK (TO-251) 175 Package Overview Top and Bottom Side Cooling of SMD Devices For LV MOSFETs different SMD packages such as SuperSO8, CanPAK™ and Blade are available. If the cooling system is designed for main heatflow to the PCB both packages will show similar thermal performance. If the main heat flow is to the top side the CanPAK™ is the better choice since the thermal resistance to the top side is lower (Rth_top_CanPAK™ ~ 1 K/W, Rth_top_SuperSO8 ~ 20 K/W). Bottom side cooling Top side cooling top Heatsink top Package PCB PPCB > Pheatsink bottom Thermal performance CanPAK™ ~ SuperSO8 Example: High performance Server (PCB: 8 layer, 70µm) PPCB < Pheatsink bottom Thermal performance CanPAK™ > SuperSO8 Example: Motherboard (PCB 4 layer, 35µm) with high performance heatsink New IGBT Technology RCD Allows Highest Power Density with Small SMD Packages The new IGBT RCD technology in combination with an efficient cooling system allows to use small SMD packages which enable to build compact systems with increased power density. In order to improve the heat dissipation, thermal vias are integrated in the PCB under the device case which results in a low thermal resistance to the opposite side of the PCB. A heatsink complements the cooling system. Isolation to the heatsink is realized with a thermal foil. With this cooling system power dissipation up to 7 to 10W / IGBT is achievable which corresponds to ~ 2kW application systems. 176 Package Overview OptiMOS™ in TO-Leadless A Package Optimized For High Current Applications TO-Leadless has been designed for high currents up to 300A. In addition, latest OptiMOS™ Silicon technology in combination with reduced package resistance achieves lowest RDS(on). This enables a reduction in the number of parallel MOSFETs in a Forklift application and increases power density. Further the 60% smaller package size enables a very compact design. Compared to D²PAK 7pin, TO-Leadless shows a substantial reduction in footprint of 30%. The 50% reduced height offers a significant advantage in applications where compact designs are key, such as Rack or Blade Servers. Moreover low package parasitic inductances result in an improved EMI behavior and a 50% bigger solder contact area avoids electro migration at high current levels, which results in improved reliability. Applications Forklift Light Electric Vehicles Point of Load (PoL) Telecom e-fuse Features Industry‘s lowest RDS(on) Highest current capability up to 300A Very low package parasitics and inductances Less paralleling and cooling required Highest system reliability System cost reduction Enabling very compact design 4.4mm 2.3mm 15.0mm Footprint: 150mm2 9.9mm 11.7mm Footprint: 115mm2 Packages 10.0mm 177 Package Overview TO- 247 4pin Full Load Efficiency for Free Benefits Full load efficiency Improved EMI Better gate control Increased creepage Package for High voltage switches with increased creepage and clearance Infineon’s TO-247 4pin package enables significant efficiency improvement in hard switched topologies and allows a better control at the same time. The fourth pin acts as kelvin source. The main current of the switch is placed outside of the gate loop and the feedback is eliminated. This leads especially at high currents to less switching losses. Secondly, the EMI will be reduced due to cleaner waveforms. The benefit will be seen in various hard switching topologies used in AC/ DC and DC/AC conversion. The package helps as well in designs where the next current or RDS(on) class with a three pin approach must be chosen in high load operation. This is related to the improved efficiency by 5 to 8% at such operation condition. C VDRV Collector G RG PWM IG C E1 E2 Gate Emitter + VLS – E1 E2 G C Package Power Loop Chip Collector G G C E Gate Emitter ~13nh TO-247 Control Loop E 10000 Etot [µJ] 8000 6000 4000 2000 0 0 25 50 75 IC(sw) [A] Comp. A 178 TO-247 3pin TO-247 4pin 100 Package Overview TO-247PLUS Responding to the market requirement to accommodate ever increasing amounts of silicon in smaller, space saving packages, Infineon introduces the new package TO-247PLUS . Higher Current Capability - Improved Thermal Behavior Infineon’s new TO-247PLUS has the same outer dimensions as the industry standard TO-247, but due to the absence of the screw hole, allows up to 120A in 600V. Also the total backside active thermal pad area has been increased to improve heat dissipation capabilities of the package. Improved Thermal Management and Creepage Distances Better heat dissipation through lower Rth improves thermal management, which means less heat sink and lower cost for the cooling infrastructure. TO247PLUS package body has special “plastic trousers”, that allows to increase the creepage distance to 4.25mm – 2mm bigger than the standard TO-247. Special cut-outs of the mold compound at the upper corners, increase creepage path at single clip mounting. Moreover, the TO-247PLUS plastic body has tighter tolerances to clip pressure comparing to the major competitors on the market, thus contributing for better reliability of the device use in application. A new bond wiring concept realized in TO-247PLUS package allows increase of the DC collector current from 80A to 160A (at Tc = 25°C) contributing to the better reliability and longer lifetime of the IGBT. TO-247PLUS 100A/120A is qualified according to industrial/automotive standards. Applications UPS Solar Welding Drives AirCon/ HVAC Automotive Features Highest current rating co-pack 600V in 100A and 120A 35% bigger active thermal pad area for up to 20% lower thermal resistance Rth(jh) Extended creepage distance of 4.25mm – 2mm bigger than TO-247 Benefits Higher system power density – IC increase keeping the same system thermal performance Lower thermal resistance Rth(jh) and improved by ~15% heat dissipation capability of TO-247PLUS vs TO-247 Higher reliability, extended lifetime of the device TO-247 Major Differences TO-247PLUS Screw hole vs. no screw hole Maximum allowable chip area in single die ~70mm² vs 120mm² Current capability (DuoPAK) 600V: 75A vs 120A (+60%) Increased creepage by 52% to 4.25mm Bond wire limit increased from 80A to 160A Bigger backside active thermal pad area due to missing hole 140mm² vs 190mm² Packages 20% lower thermal resistance Rth(jh) 10%-15% better heat dissipation 179 Free On-Demand Webinars and Videos Stay on Track with our High Level Online Content Free On Demand Webinars Featuring a variety of topics 45-60 minutes in length Register once to get access to all content, including documentation Watch at your convenient www.infineon.com/on-demand-webinar Power Management Expert Videos Infineon experts giving digital lectures Application, topology, evaluation board and product focus Updates on new technologies and products Knowledge and expertise sharing www.infineon.com/mediacenter www.youtube.com/infineontechnologies On-Demand Webinars We shape Power Management – We live Energy Efficiency www.infineon.com/energyefficiency Ask Infineon. Get connected with the answers. Infineon offers its toll-free 0800/4001 service hotline as one central number, available 24/7 in English, Mandarin and German. Our global connection service goes way beyond standard switchboard services by offering qualified support on the phone. Call us! Germany ................... 0800 951 951 951 (German/English) China, mainland ....... 4001 200 951 (Mandarin/English) India .......................... 000 800 4402 951 (English) USA ............................ 1-866 951 9519 (English/German) Other countries ......... 00* 800 951 951 951 (English/German) Direct access ............. +49 89 234-0 (interconnection fee, German/English) * Please note: Some countries may require you to dial a code other than “00” to access this international number, please visit www.infineon.com/service for your country! Where to Buy Infineon Distribution Partners and Sales Offices: www.infineon.com/WhereToBuy Stay connected Mobile Product Catalog www.facebook.com/infineon www.twitter.com/infineon www.infineon.com/linkedin www.infineon.com/xing www.youtube.com/infineon Published by Infineon Technologies Austria AG 9500 Villach, Austria © 2015 Infineon Technologies AG. All Rights Reserved. Visit us: www.infineon.com Order Number: B111-I0079-V1-7600-EU-EC-P Date: 02 / 2015 Attention please! The information given in this document shall in no event be regarded as a guarantee of conditions or characteristics (“Beschaffenheitsgarantie”). With respect to any examples or hints given herein, any typical values stated herein and/ or any information regarding the application of the device, Infineon Technologies hereby disclaims any and all warranties and liabilities of any kind, including without limitation warranties of non-infringement of intellectual property rights of any third party. Information For further information on technology, delivery terms and conditions and prices please contact your nearest Infineon Technologies Office (www.infineon.com). Warnings Due to technical requirements components may contain dangerous substances. For information on the types in question please contact your nearest Infineon Technologies Office. Infineon Technologies Components may only be used in life-support devices or systems with the express written approval of Infineon Technologies, if a failure of such components can reasonably be expected to cause the failure of that life-support device or system, or to affect the safety or effectiveness of that device or system. Life support devices or systems are intended to be implanted in the human body, or to support and/or maintain and sustain and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons may be endangered.